probability and statistics for engineering and the sciences

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Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. EIGHTH EDITION Probability and Statistics for Engineering and the Sciences JAY DEVORE California Polytechnic State University, San Luis Obispo Australia • Brazil • Canada • Mexico • Singapore • Spain United Kingdom • United States Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1019763_FM_VOL-I.qxp 9/17/07 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 S 50 R 51 4:22 PM Page viii This page was intentionally left blank 1st Pass Pages This is an electronic version of the print textbook. Due to electronic rights restrictions, some third party content may be suppressed. Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. The publisher reserves the right to remove content from this title at any time if subsequent rights restrictions require it. For valuable information on pricing, previous editions, changes to current editions, and alternate formats, please visit www.cengage.com/highered to search by ISBN#, author, title, or keyword for materials in your areas of interest. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Probability and Statistics for Engineering and the Sciences, Eighth Edition Jay L. Devore Editor in Chief: Michelle Julet Publisher: Richard Stratton Senior Sponsoring Editor: Molly Taylor Senior Development Editor: Jay Campbell © 2012, 2009 Brooks/Cole, Cengage Learning ALL RIGHTS RESERVED. 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Library of Congress Control Number: 2010927429 ISBN-13: 978-0-538-73352-6 ISBN-10: 0-538-73352-7 Brooks/Cole 20 Channel Center Street Boston, MA 02210 USA Cengage Learning is a leading provider of customized learning solutions with office locations around the globe, including Singapore, the United Kingdom, Australia, Mexico, Brazil, and Japan. Locate your local office at international.cengage.com/region Cengage Learning products are represented in Canada by Nelson Education, Ltd. For your course and learning solutions, visit www.cengage.com. Purchase any of our products at your local college store or at our preferred online store www.cengagebrain.com. Printed in the United States of America 1 2 3 4 5 6 7 14 13 12 11 10 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. To my grandson Philip, who is highly statistically significant. v Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Contents 1 Overview and Descriptive Statistics 1.1 1.2 1.3 1.4 Introduction 1 Populations, Samples, and Processes 2 Pictorial and Tabular Methods in Descriptive Statistics 12 Measures of Location 28 Measures of Variability 35 Supplementary Exercises 46 Bibliography 49 2 Probability 2.1 2.2 2.3 2.4 2.5 Introduction 50 Sample Spaces and Events 51 Axioms, Interpretations, and Properties of Probability 55 Counting Techniques 64 Conditional Probability 73 Independence 83 Supplementary Exercises 88 Bibliography 91 3 Discrete Random Variables and Probability Distributions 3.1 3.2 3.3 3.4 3.5 3.6 Introduction 92 Random Variables 93 Probability Distributions for Discrete Random Variables 96 Expected Values 106 The Binomial Probability Distribution 114 Hypergeometric and Negative Binomial Distributions 122 The Poisson Probability Distribution 128 Supplementary Exercises 133 Bibliography 136 vii Copyright 2010 Cengage Learning. All Rights Reserved. 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Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. viii Contents 4 Continuous Random Variables and Probability Distributions 4.1 4.2 4.3 4.4 4.5 4.6 Introduction 137 Probability Density Functions 138 Cumulative Distribution Functions and Expected Values 143 The Normal Distribution 152 The Exponential and Gamma Distributions 165 Other Continuous Distributions 171 Probability Plots 178 Supplementary Exercises 188 Bibliography 192 5 Joint Probability Distributions and Random Samples 5.1 5.2 5.3 5.4 5.5 Introduction 193 Jointly Distributed Random Variables 194 Expected Values, Covariance, and Correlation 206 Statistics and Their Distributions 212 The Distribution of the Sample Mean 223 The Distribution of a Linear Combination 230 Supplementary Exercises 235 Bibliography 238 6 Point Estimation Introduction 239 6.1 Some General Concepts of Point Estimation 240 6.2 Methods of Point Estimation 255 Supplementary Exercises 265 Bibliography 266 7 Statistical Intervals Based on a Single Sample Introduction 267 7.1 Basic Properties of Confidence Intervals 268 7.2 Large-Sample Confidence Intervals for a Population Mean and Proportion 276 Copyright 2010 Cengage Learning. 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Contents ix 7.3 Intervals Based on a Normal Population Distribution 285 7.4 Confidence Intervals for the Variance and Standard Deviation of a Normal Population 294 Supplementary Exercises 297 Bibliography 299 8 Tests of Hypotheses Based on a Single Sample 8.1 8.2 8.3 8.4 8.5 Introduction 300 Hypotheses and Test Procedures 301 Tests About a Population Mean 310 Tests Concerning a Population Proportion 323 P-Values 328 Some Comments on Selecting a Test 339 Supplementary Exercises 342 Bibliography 344 9 Inferences Based on Two Samples 9.1 9.2 9.3 9.4 9.5 Introduction 345 z Tests and Confidence Intervals for a Difference Between Two Population Means 346 The Two-Sample t Test and Confidence Interval 357 Analysis of Paired Data 365 Inferences Concerning a Difference Between Population Proportions 375 Inferences Concerning Two Population Variances 382 Supplementary Exercises 386 Bibliography 390 10 The Analysis of Variance Introduction 391 10.1 Single-Factor ANOVA 392 10.2 Multiple Comparisons in ANOVA 402 10.3 More on Single-Factor ANOVA 408 Supplementary Exercises 417 Bibliography 418 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. x Contents 11 Multifactor Analysis of Variance 11.1 11.2 11.3 11.4 Introduction 419 Two-Factor ANOVA with Kij ⫽ 1 420 Two-Factor ANOVA with Kij ⬎ 1 433 Three-Factor ANOVA 442 2p Factorial Experiments 451 Supplementary Exercises 464 Bibliography 467 12 Simple Linear Regression and Correlation Introduction 468 The Simple Linear Regression Model 469 Estimating Model Parameters 477 Inferences About the Slope Parameter ␤1 490 Inferences Concerning mY # x * and the Prediction of Future Y Values 499 12.5 Correlation 508 Supplementary Exercises 518 Bibliography 522 12.1 12.2 12.3 12.4 13 Nonlinear and Multiple Regression 13.1 13.2 13.3 13.4 13.5 Introduction 523 Assessing Model Adequacy 524 Regression with Transformed Variables 531 Polynomial Regression 543 Multiple Regression Analysis 553 Other Issues in Multiple Regression 574 Supplementary Exercises 588 Bibliography 593 14 Goodness-of-Fit Tests and Categorical Data Analysis Introduction 594 14.1 Goodness-of-Fit Tests When Category Probabilities Are Completely Specified 595 Copyright 2010 Cengage Learning. 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Contents xi 14.2 Goodness-of-Fit Tests for Composite Hypotheses 602 14.3 Two-Way Contingency Tables 613 Supplementary Exercises 621 Bibliography 624 15 Distribution-Free Procedures 15.1 15.2 15.3 15.4 Introduction 625 The Wilcoxon Signed-Rank Test 626 The Wilcoxon Rank-Sum Test 634 Distribution-Free Confidence Intervals 640 Distribution-Free ANOVA 645 Supplementary Exercises 649 Bibliography 650 16 Quality Control Methods 16.1 16.2 16.3 16.4 16.5 16.6 Introduction 651 General Comments on Control Charts 652 Control Charts for Process Location 654 Control Charts for Process Variation 663 Control Charts for Attributes 668 CUSUM Procedures 672 Acceptance Sampling 680 Supplementary Exercises 686 Bibliography 687 Appendix Tables A.1 A.2 A.3 A.4 A.5 A.6 A.7 A.8 A.9 A.10 Cumulative Binomial Probabilities A-2 Cumulative Poisson Probabilities A-4 Standard Normal Curve Areas A-6 The Incomplete Gamma Function A-8 Critical Values for t Distributions A-9 Tolerance Critical Values for Normal Population Distributions A-10 Critical Values for Chi-Squared Distributions A-11 t Curve Tail Areas A-12 Critical Values for F Distributions A-14 Critical Values for Studentized Range Distributions A-20 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. xii Contents A.11 A.12 A.13 A.14 A.15 A.16 A.17 Chi-Squared Curve Tail Areas A-21 Critical Values for the Ryan-Joiner Test of Normality A-23 Critical Values for the Wilcoxon Signed-Rank Test A-24 Critical Values for the Wilcoxon Rank-Sum Test A-25 Critical Values for the Wilcoxon Signed-Rank Interval A-26 Critical Values for the Wilcoxon Rank-Sum Interval A-27 ␤ Curves for t Tests A-28 Answers to Selected Odd-Numbered Exercises A-29 Glossary of Symbols/Abbreviations G-1 Index I-1 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Preface Purpose The use of probability models and statistical methods for analyzing data has become common practice in virtually all scientific disciplines. This book attempts to provide a comprehensive introduction to those models and methods most likely to be encountered and used by students in their careers in engineering and the natural sciences. Although the examples and exercises have been designed with scientists and engineers in mind, most of the methods covered are basic to statistical analyses in many other disciplines, so that students of business and the social sciences will also profit from reading the book. Approach Students in a statistics course designed to serve other majors may be initially skeptical of the value and relevance of the subject matter, but my experience is that students can be turned on to statistics by the use of good examples and exercises that blend their everyday experiences with their scientific interests. Consequently, I have worked hard to find examples of real, rather than artificial, data—data that someone thought was worth collecting and analyzing. Many of the methods presented, especially in the later chapters on statistical inference, are illustrated by analyzing data taken from published sources, and many of the exercises also involve working with such data. Sometimes the reader may be unfamiliar with the context of a particular problem (as indeed I often was), but I have found that students are more attracted by real problems with a somewhat strange context than by patently artificial problems in a familiar setting. Mathematical Level The exposition is relatively modest in terms of mathematical development. Substantial use of the calculus is made only in Chapter 4 and parts of Chapters 5 and 6. In particular, with the exception of an occasional remark or aside, calculus appears in the inference part of the book only—in the second section of Chapter 6. Matrix algebra is not used at all. Thus almost all the exposition should be accessible to those whose mathematical background includes one semester or two quarters of differential and integral calculus. Content Chapter 1 begins with some basic concepts and terminology—population, sample, descriptive and inferential statistics, enumerative versus analytic studies, and so on— and continues with a survey of important graphical and numerical descriptive methods. A rather traditional development of probability is given in Chapter 2, followed by probability distributions of discrete and continuous random variables in Chapters 3 and 4, respectively. Joint distributions and their properties are discussed in the first part of Chapter 5. The latter part of this chapter introduces statistics and their sampling distributions, which form the bridge between probability and inference. The next three chapters cover point estimation, statistical intervals, and hypothesis testing based on a single sample. Methods of inference involving two independent samples and paired data are presented in Chapter 9. The analysis of variance is the subject of Chapters 10 and 11 (single-factor and multifactor, respectively). Regression makes its initial appearance in Chapter 12 (the simple linear regression model and correlation) and xiii Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. xiv Preface returns for an extensive encore in Chapter 13. The last three chapters develop chisquared methods, distribution-free (nonparametric) procedures, and techniques from statistical quality control. Helping Students Learn Although the book’s mathematical level should give most science and engineering students little difficulty, working toward an understanding of the concepts and gaining an appreciation for the logical development of the methodology may sometimes require substantial effort. To help students gain such an understanding and appreciation, I have provided numerous exercises ranging in difficulty from many that involve routine application of text material to some that ask the reader to extend concepts discussed in the text to somewhat new situations. There are many more exercises than most instructors would want to assign during any particular course, but I recommend that students be required to work a substantial number of them; in a problem-solving discipline, active involvement of this sort is the surest way to identify and close the gaps in understanding that inevitably arise. Answers to most oddnumbered exercises appear in the answer section at the back of the text. In addition, a Student Solutions Manual, consisting of worked-out solutions to virtually all the odd-numbered exercises, is available. To access additional course materials and companion resources, please visit www.cengagebrain.com. At the CengageBrain.com home page, search for the ISBN of your title (from the back cover of your book) using the search box at the top of the page. This will take you to the product page where free companion resources can be found. New for This Edition • A Glossary of Symbols/Abbreviations appears at the end of the book (the author apologizes for his laziness in not getting this together for earlier editions!) and a small set of sample exams appears on the companion website (available at www.cengage.com/login). • Many new examples and exercises, almost all based on real data or actual problems. Some of these scenarios are less technical or broader in scope than what has been included in previous editions—for example, weights of football players (to illustrate multimodality), fundraising expenses for charitable organizations, and the comparison of grade point averages for classes taught by part-time faculty with those for classes taught by full-time faculty. • The material on P-values has been substantially rewritten. The P-value is now initially defined as a probability rather than as the smallest significance level for which the null hypothesis can be rejected. A simulation experiment is presented to illustrate the behavior of P-values. • Chapter 1 contains a new subsection on “The Scope of Modern Statistics” to indicate how statisticians continue to develop new methodology while working on problems in a wide spectrum of disciplines. • The exposition has been polished whenever possible to help students gain an intuitive understanding of various concepts. For example, the cumulative distribution function is more deliberately introduced in Chapter 3, the first example of maximum likelihood in Section 6.2 contains a more careful discussion of likelihood, more attention is given to power and type II error probabilities in Section 8.3, and the material on residuals and sums of squares in multiple regression is laid out more explicitly in Section 13.4. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Preface xv Acknowledgments My colleagues at Cal Poly have provided me with invaluable support and feedback over the years. I am also grateful to the many users of previous editions who have made suggestions for improvement (and on occasion identified errors). A special note of thanks goes to Matt Carlton for his work on the two solutions manuals, one for instructors and the other for students. The generous feedback provided by the following reviewers of this and previous editions has been of great benefit in improving the book: Robert L. Armacost, University of Central Florida; Bill Bade, Lincoln Land Community College; Douglas M. Bates, University of Wisconsin–Madison; Michael Berry, West Virginia Wesleyan College; Brian Bowman, Auburn University; Linda Boyle, University of Iowa; Ralph Bravaco, Stonehill College; Linfield C. Brown, Tufts University; Karen M. Bursic, University of Pittsburgh; Lynne Butler, Haverford College; Raj S. Chhikara, University of Houston–Clear Lake; Edwin Chong, Colorado State University; David Clark, California State Polytechnic University at Pomona; Ken Constantine, Taylor University; David M. Cresap, University of Portland; Savas Dayanik, Princeton University; Don E. Deal, University of Houston; Annjanette M. Dodd, Humboldt State University; Jimmy Doi, California Polytechnic State University–San Luis Obispo; Charles E. Donaghey, University of Houston; Patrick J. Driscoll, U.S. Military Academy; Mark Duva, University of Virginia; Nassir Eltinay, Lincoln Land Community College; Thomas English, College of the Mainland; Nasser S. Fard, Northeastern University; Ronald Fricker, Naval Postgraduate School; Steven T. Garren, James Madison University; Mark Gebert, University of Kentucky; Harland Glaz, University of Maryland; Ken Grace, Anoka-Ramsey Community College; Celso Grebogi, University of Maryland; Veronica Webster Griffis, Michigan Technological University; Jose Guardiola, Texas A&M University–Corpus Christi; K. L. D. Gunawardena, University of Wisconsin–Oshkosh; James J. Halavin, Rochester Institute of Technology; James Hartman, Marymount University; Tyler Haynes, Saginaw Valley State University; Jennifer Hoeting, Colorado State University; Wei-Min Huang, Lehigh University; Aridaman Jain, New Jersey Institute of Technology; Roger W. Johnson, South Dakota School of Mines & Technology; Chihwa Kao, Syracuse University; Saleem A. Kassam, University of Pennsylvania; Mohammad T. Khasawneh, State University of NewYork–Binghamton; Stephen Kokoska, Colgate University; Hillel J. Kumin, University of Oklahoma; Sarah Lam, Binghamton University; M. Louise Lawson, Kennesaw State University; Jialiang Li, University of Wisconsin–Madison; Wooi K. Lim, William Paterson University; Aquila Lipscomb, The Citadel; Manuel Lladser, University of Colorado at Boulder; Graham Lord, University of California–Los Angeles; Joseph L. Macaluso, DeSales University; Ranjan Maitra, Iowa State University; David Mathiason, Rochester Institute of Technology; Arnold R. Miller, University of Denver; John J. Millson, University of Maryland; Pamela Kay Miltenberger, West Virginia Wesleyan College; Monica Molsee, Portland State University; Thomas Moore, Naval Postgraduate School; Robert M. Norton, College of Charleston; Steven Pilnick, Naval Postgraduate School; Robi Polikar, Rowan University; Ernest Pyle, Houston Baptist University; Steve Rein, California Polytechnic State University–San Luis Obispo; Tony Richardson, University of Evansville; Don Ridgeway, North Carolina State University; Larry J. Ringer, Texas A&M University; Robert M. Schumacher, Cedarville University; Ron Schwartz, Florida Atlantic University; Kevan Shafizadeh, California State University–Sacramento; Mohammed Shayib, Prairie View A&M; Robert K. Smidt, California Polytechnic State University–San Luis Obispo; Alice E. Smith, Auburn University; James MacGregor Smith, University of Massachusetts; Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. xvi Preface Paul J. Smith, University of Maryland; Richard M. Soland, The George Washington University; Clifford Spiegelman, Texas A & M University; Jery Stedinger, Cornell University; David Steinberg, Tel Aviv University; William Thistleton, State University of New York Institute of Technology; G. Geoffrey Vining, University of Florida; Bhutan Wadhwa, Cleveland State University; Gary Wasserman, Wayne State University; Elaine Wenderholm, State University of New York–Oswego; Samuel P. Wilcock, Messiah College; Michael G. Zabetakis, University of Pittsburgh; and Maria Zack, Point Loma Nazarene University. Danielle Urban of Elm Street Publishing Services has done a terrific job of supervising the book's production. Once again I am compelled to express my gratitude to all those people at Cengage who have made important contributions over the course of my textbook writing career. For this most recent edition, special thanks go to Jay Campbell (for his timely and informed feedback throughout the project), Molly Taylor, Shaylin Walsh, Ashley Pickering, Cathy Brooks, and Andrew Coppola. I also greatly appreciate the stellar work of all those Cengage Learning sales representatives who have labored to make my books more visible to the statistical community. Last but by no means least, a heartfelt thanks to my wife Carol for her decades of support, and to my daughters for providing inspiration through their own achievements. Jay Devore Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1 Overview and Descriptive Statistics “I am not much given to regret, so I puzzled over this one a while. Should have taken much more statistics in college, I think.” —Max Levchin, Paypal Co-founder, Slide Founder Quote of the week from the Web site of the American Statistical Association on November 23, 2010 “I keep saying that the sexy job in the next 10 years will be statisticians, and I’m not kidding.” —Hal Varian, Chief Economist at Google August 6, 2009, The New York Times INTRODUCTION Statistical concepts and methods are not only useful but indeed often indispensable in understanding the world around us. They provide ways of gaining new insights into the behavior of many phenomena that you will encounter in your chosen field of specialization in engineering or science. The discipline of statistics teaches us how to make intelligent judgments and informed decisions in the presence of uncertainty and variation. Without uncertainty or variation, there would be little need for statistical methods or statisticians. If every component of a particular type had exactly the same lifetime, if all resistors produced by a certain manufacturer had the same resistance value, if pH determinations for soil specimens from a particular locale gave identical results, and so on, then a single observation would reveal all desired information. An interesting manifestation of variation arises in the course of performing emissions testing on motor vehicles. The expense and time requirements of the Federal Test Procedure (FTP) preclude its widespread use in vehicle inspection programs. As a result, many agencies have developed less costly and quicker tests, which it is hoped replicate FTP results. According to the journal article “Motor 1 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2 CHAPTER 1 Overview and Descriptive Statistics Vehicle Emissions Variability” (J. of the Air and Waste Mgmt. Assoc., 1996: 667–675), the acceptance of the FTP as a gold standard has led to the widespread belief that repeated measurements on the same vehicle would yield identical (or nearly identical) results. The authors of the article applied the FTP to seven vehicles characterized as “high emitters.” Here are the results for one such vehicle: HC (gm/mile) 13.8 18.3 32.2 32.5 CO (gm/mile) 118 149 232 236 The substantial variation in both the HC and CO measurements casts considerable doubt on conventional wisdom and makes it much more difficult to make precise assessments about emissions levels. How can statistical techniques be used to gather information and draw conclusions? Suppose, for example, that a materials engineer has developed a coating for retarding corrosion in metal pipe under specified circumstances. If this coating is applied to different segments of pipe, variation in environmental conditions and in the segments themselves will result in more substantial corrosion on some segments than on others. Methods of statistical analysis could be used on data from such an experiment to decide whether the average amount of corrosion exceeds an upper specification limit of some sort or to predict how much corrosion will occur on a single piece of pipe. Alternatively, suppose the engineer has developed the coating in the belief that it will be superior to the currently used coating. A comparative experiment could be carried out to investigate this issue by applying the current coating to some segments of pipe and the new coating to other segments. This must be done with care lest the wrong conclusion emerge. For example, perhaps the average amount of corrosion is identical for the two coatings. However, the new coating may be applied to segments that have superior ability to resist corrosion and under less stressful environmental conditions compared to the segments and conditions for the current coating. The investigator would then likely observe a difference between the two coatings attributable not to the coatings themselves, but just to extraneous variation. Statistics offers not only methods for analyzing the results of experiments once they have been carried out but also suggestions for how experiments can be performed in an efficient manner to mitigate the effects of variation and have a better chance of producing correct conclusions. 1.1 Populations, Samples, and Processes Engineers and scientists are constantly exposed to collections of facts, or data, both in their professional capacities and in everyday activities. The discipline of statistics provides methods for organizing and summarizing data and for drawing conclusions based on information contained in the data. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.1 Populations, Samples, and Processes 3 An investigation will typically focus on a well-defined collection of objects constituting a population of interest. In one study, the population might consist of all gelatin capsules of a particular type produced during a specified period. Another investigation might involve the population consisting of all individuals who received a B.S. in engineering during the most recent academic year. When desired information is available for all objects in the population, we have what is called a census. Constraints on time, money, and other scarce resources usually make a census impractical or infeasible. Instead, a subset of the population—a sample—is selected in some prescribed manner. Thus we might obtain a sample of bearings from a particular production run as a basis for investigating whether bearings are conforming to manufacturing specifications, or we might select a sample of last year’s engineering graduates to obtain feedback about the quality of the engineering curricula. We are usually interested only in certain characteristics of the objects in a population: the number of flaws on the surface of each casing, the thickness of each capsule wall, the gender of an engineering graduate, the age at which the individual graduated, and so on. A characteristic may be categorical, such as gender or type of malfunction, or it may be numerical in nature. In the former case, the value of the characteristic is a category (e.g., female or insufficient solder), whereas in the latter case, the value is a number (e.g., age 5 23 years or diameter 5 .502 cm). A variable is any characteristic whose value may change from one object to another in the population. We shall initially denote variables by lowercase letters from the end of our alphabet. Examples include x 5 brand of calculator owned by a student y 5 number of visits to a particular Web site during a specified period z 5 braking distance of an automobile under specified conditions Data results from making observations either on a single variable or simultaneously on two or more variables. A univariate data set consists of observations on a single variable. For example, we might determine the type of transmission, automatic (A) or manual (M), on each of ten automobiles recently purchased at a certain dealership, resulting in the categorical data set M A A A M A A M A A The following sample of lifetimes (hours) of brand D batteries put to a certain use is a numerical univariate data set: 5.6 5.1 6.2 6.0 5.8 6.5 5.8 5.5 We have bivariate data when observations are made on each of two variables. Our data set might consist of a (height, weight) pair for each basketball player on a team, with the first observation as (72, 168), the second as (75, 212), and so on. If an engineer determines the value of both x 5 component lifetime and y 5 reason for component failure, the resulting data set is bivariate with one variable numerical and the other categorical. Multivariate data arises when observations are made on more than one variable (so bivariate is a special case of multivariate). For example, a research physician might determine the systolic blood pressure, diastolic blood pressure, and serum cholesterol level for each patient participating in a study. Each observation would be a triple of numbers, such as (120, 80, 146). In many multivariate data sets, some variables are numerical and others are categorical. Thus the annual automobile issue of Consumer Reports gives values of such variables as type of vehicle (small, sporty, compact, mid-size, large), city fuel efficiency (mpg), highway fuel efficiency (mpg), drivetrain type (rear wheel, front wheel, four wheel), and so on. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4 CHAPTER 1 Overview and Descriptive Statistics Branches of Statistics An investigator who has collected data may wish simply to summarize and describe important features of the data. This entails using methods from descriptive statistics. Some of these methods are graphical in nature; the construction of histograms, boxplots, and scatter plots are primary examples. Other descriptive methods involve calculation of numerical summary measures, such as means, standard deviations, and correlation coefficients. The wide availability of statistical computer software packages has made these tasks much easier to carry out than they used to be. Computers are much more efficient than human beings at calculation and the creation of pictures (once they have received appropriate instructions from the user!). This means that the investigator doesn’t have to expend much effort on “grunt work” and will have more time to study the data and extract important messages. Throughout this book, we will present output from various packages such as Minitab, SAS, S-Plus, and R. The R software can be downloaded without charge from the site http://www.r-project.org. Example 1.1 Charity is a big business in the United States. The Web site charitynavigator.com gives information on roughly 5500 charitable organizations, and there are many smaller charities that fly below the navigator’s radar screen. Some charities operate very efficiently, with fundraising and administrative expenses that are only a small percentage of total expenses, whereas others spend a high percentage of what they take in on such activities. Here is data on fundraising expenses as a percentage of total expenditures for a random sample of 60 charities: 6.1 2.2 7.5 6.4 8.8 15.3 12.6 3.1 3.9 10.8 5.1 16.6 34.7 1.3 10.1 83.1 3.7 8.8 1.6 1.1 8.1 3.6 26.3 12.0 18.8 14.1 19.5 6.2 6.0 4.7 2.2 4.0 5.2 6.3 48.0 14.7 3.0 21.0 12.0 16.3 8.2 6.4 2.2 6.1 15.8 12.7 11.7 17.0 5.6 1.3 10.4 1.3 7.2 2.5 3.8 20.4 5.2 0.8 3.9 16.2 Without any organization, it is difficult to get a sense of the data’s most prominent features—what a typical (i.e. representative) value might be, whether values are highly concentrated about a typical value or quite dispersed, whether there are any 40 30 Frequency Stem–and–leaf of FundRsng N = 60 Leaf Unit = 1.0 0 0111112222333333344 0 55556666666778888 1 0001222244 1 55666789 2 01 2 6 3 4 3 4 4 8 5 5 6 6 7 7 8 3 20 10 0 0 10 20 30 40 50 FundRsng 60 70 80 90 Figure 1.1 A Minitab stem-and-leaf display (tenths digit truncated) and histogram for the charity fundraising percentage data Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.1 Populations, Samples, and Processes 5 gaps in the data, what fraction of the values are less than 20%, and so on. Figure 1.1 shows what is called a stem-and-leaf display as well as a histogram. In Section 1.2 we will discuss construction and interpretation of these data summaries. For the moment, we hope you see how they begin to describe how the percentages are distributed over the range of possible values from 0 to 100. Clearly a substantial majority of the charities in the sample spend less than 20% on fundraising, and only a few percentages might be viewed as beyond the bounds of sensible practice. ■ Having obtained a sample from a population, an investigator would frequently like to use sample information to draw some type of conclusion (make an inference of some sort) about the population. That is, the sample is a means to an end rather than an end in itself. Techniques for generalizing from a sample to a population are gathered within the branch of our discipline called inferential statistics. Example 1.2 Material strength investigations provide a rich area of application for statistical methods. The article “Effects of Aggregates and Microfillers on the Flexural Properties of Concrete” (Magazine of Concrete Research, 1997: 81–98) reported on a study of strength properties of high-performance concrete obtained by using superplasticizers and certain binders. The compressive strength of such concrete had previously been investigated, but not much was known about flexural strength (a measure of ability to resist failure in bending). The accompanying data on flexural strength (in MegaPascal, MPa, where 1 Pa (Pascal) 5 1.45 3 1024 psi) appeared in the article cited: 5.9 8.2 7.2 7.3 8.7 7.8 6.3 9.7 8.1 7.4 6.8 7.7 7.0 9.7 7.6 7.8 6.8 7.7 6.5 11.6 7.0 11.3 6.3 11.8 7.9 10.7 9.0 Suppose we want an estimate of the average value of flexural strength for all beams that could be made in this way (if we conceptualize a population of all such beams, we are trying to estimate the population mean). It can be shown that, with a high degree of confidence, the population mean strength is between 7.48 MPa and 8.80 MPa; we call this a confidence interval or interval estimate. Alternatively, this data could be used to predict the flexural strength of a single beam of this type. With a high degree of confidence, the strength of a single such beam will exceed 7.35 MPa; the number 7.35 is called a lower prediction bound. ■ The main focus of this book is on presenting and illustrating methods of inferential statistics that are useful in scientific work. The most important types of inferential procedures—point estimation, hypothesis testing, and estimation by confidence intervals—are introduced in Chapters 6–8 and then used in more complicated settings in Chapters 9–16. The remainder of this chapter presents methods from descriptive statistics that are most used in the development of inference. Chapters 2–5 present material from the discipline of probability. This material ultimately forms a bridge between the descriptive and inferential techniques. Mastery of probability leads to a better understanding of how inferential procedures are developed and used, how statistical conclusions can be translated into everyday language and interpreted, and when and where pitfalls can occur in applying the methods. Probability and statistics both deal with questions involving populations and samples, but do so in an “inverse manner” to one another. In a probability problem, properties of the population under study are assumed known (e.g., in a numerical population, some specified distribution of the population values may be assumed), and questions regarding a sample taken from the population are posed and answered. In a statistics problem, characteristics of a Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6 CHAPTER 1 Overview and Descriptive Statistics Probability Sample Population Inferential statistics Figure 1.2 The relationship between probability and inferential statistics sample are available to the experimenter, and this information enables the experimenter to draw conclusions about the population. The relationship between the two disciplines can be summarized by saying that probability reasons from the population to the sample (deductive reasoning), whereas inferential statistics reasons from the sample to the population (inductive reasoning). This is illustrated in Figure 1.2. Before we can understand what a particular sample can tell us about the population, we should first understand the uncertainty associated with taking a sample from a given population. This is why we study probability before statistics. Example 1.3 As an example of the contrasting focus of probability and inferential statistics, consider drivers’ use of manual lap belts in cars equipped with automatic shoulder belt systems. (The article “Automobile Seat Belts: Usage Patterns in Automatic Belt Systems,” Human Factors, 1998: 126–135, summarizes usage data.) In probability, we might assume that 50% of all drivers of cars equipped in this way in a certain metropolitan area regularly use their lap belt (an assumption about the population), so we might ask, “How likely is it that a sample of 100 such drivers will include at least 70 who regularly use their lap belt?” or “How many of the drivers in a sample of size 100 can we expect to regularly use their lap belt?” On the other hand, in inferential statistics, we have sample information available; for example, a sample of 100 drivers of such cars revealed that 65 regularly use their lap belt. We might then ask, “Does this provide substantial evidence for concluding that more than 50% of all such drivers in this area regularly use their lap belt?” In this latter scenario, we are attempting to use sample information to answer a question about the structure of the entire population from which the sample was selected. ■ In the foregoing lap belt example, the population is well defined and concrete: all drivers of cars equipped in a certain way in a particular metropolitan area. In Example 1.2, however, the strength measurements came from a sample of prototype beams that had not been selected from an existing population. Instead, it is convenient to think of the population as consisting of all possible strength measurements that might be made under similar experimental conditions. Such a population is referred to as a conceptual or hypothetical population. There are a number of problem situations in which we fit questions into the framework of inferential statistics by conceptualizing a population. The Scope of Modern Statistics These days statistical methodology is employed by investigators in virtually all disciplines, including such areas as • molecular biology (analysis of microarray data) • ecology (describing quantitatively how individuals in various animal and plant populations are spatially distributed) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.1 Populations, Samples, and Processes 7 • materials engineering (studying properties of various treatments to retard corrosion) • marketing (developing market surveys and strategies for marketing new products) • public health (identifying sources of diseases and ways to treat them) • civil engineering (assessing the effects of stress on structural elements and the impacts of traffic flows on communities) As you progress through the book, you’ll encounter a wide spectrum of different scenarios in the examples and exercises that illustrate the application of techniques from probability and statistics. Many of these scenarios involve data or other material extracted from articles in engineering and science journals. The methods presented herein have become established and trusted tools in the arsenal of those who work with data. Meanwhile, statisticians continue to develop new models for describing randomness, and uncertainty and new methodology for analyzing data. As evidence of the continuing creative efforts in the statistical community, here are titles and capsule descriptions of some articles that have recently appeared in statistics journals (Journal of the American Statistical Association is abbreviated JASA, and AAS is short for the Annals of Applied Statistics, two of the many prominent journals in the discipline): • “Modeling Spatiotemporal Forest Health Monitoring Data” (JASA, 2009: 899–911): Forest health monitoring systems were set up across Europe in the 1980s in response to concerns about air-pollution-related forest dieback, and have continued operation with a more recent focus on threats from climate change and increased ozone levels. The authors develop a quantitative description of tree crown defoliation, an indicator of tree health. • “Active Learning Through Sequential Design, with Applications to the Detection of Money Laundering” (JASA, 2009: 969–981): Money laundering involves concealing the origin of funds obtained through illegal activities. The huge number of transactions occurring daily at financial institutions makes detection of money laundering difficult. The standard approach has been to extract various summary quantities from the transaction history and conduct a time-consuming investigation of suspicious activities. The article proposes a more efficient statistical method and illustrates its use in a case study. • “Robust Internal Benchmarking and False Discovery Rates for Detecting Racial Bias in Police Stops” (JASA, 2009: 661–668): Allegations of police actions that are attributable at least in part to racial bias have become a contentious issue in many communities. This article proposes a new method that is designed to reduce the risk of flagging a substantial number of “false positives” (individuals falsely identified as manifesting bias). The method was applied to data on 500,000 pedestrian stops in New York City in 2006; of the 3000 officers regularly involved in pedestrian stops, 15 were identified as having stopped a substantially greater fraction of Black and Hispanic people than what would be predicted were bias absent. • “Records in Athletics Through Extreme Value Theory” (JASA, 2008: 1382–1391): The focus here is on the modeling of extremes related to world records in athletics. The authors start by posing two questions: (1) What is the ultimate world record within a specific event (e.g. the high jump for women)? and (2) How “good” is the current world record, and how does the quality of current world records compare across different events? A total of 28 events (8 running, 3 throwing, and 3 jumping for both men and women) are considered. For example, one conclusion is that only about 20 seconds can be shaved off the Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 8 CHAPTER 1 Overview and Descriptive Statistics men’s marathon record, but that the current women’s marathon record is almost 5 minutes longer than what can ultimately be achieved. The methodology also has applications to such issues as ensuring airport runways are long enough and that dikes in Holland are high enough. • “Analysis of Episodic Data with Application to Recurrent Pulmonary Exacerbations in Cystic Fibrosis Patients” (JASA, 2008: 498–510): The analysis of recurrent medical events such as migraine headaches should take into account not only when such events first occur but also how long they last—length of episodes may contain important information about the severity of the disease or malady, associated medical costs, and the quality of life. The article proposes a technique that summarizes both episode frequency and length of episodes, and allows effects of characteristics that cause episode occurrence to vary over time. The technique is applied to data on cystic fibrosis patients (CF is a serious genetic disorder affecting sweat and other glands). • “Prediction of Remaining Life of Power Transformers Based on Left Truncated and Right Censored Lifetime Data” (AAS, 2009: 857–879): There are roughly 150,000 high-voltage power transmission transformers in the United States. Unexpected failures can cause substantial economic losses, so it is important to have predictions for remaining lifetimes. Relevant data can be complicated because lifetimes of some transformers extend over several decades during which records were not necessarily complete. In particular, the authors of the article use data from a certain energy company that began keeping careful records in 1980. But some transformers had been installed before January 1, 1980, and were still in service after that date (“left truncated” data), whereas other units were still in service at the time of the investigation, so their complete lifetimes are not available (“right censored” data). The article describes various procedures for obtaining an interval of plausible values (a prediction interval) for a remaining lifetime and for the cumulative number of failures over a specified time period. • “The BARISTA: A Model for Bid Arrivals in Online Auctions” (AAS, 2007: 412–441): Online auctions such as those on eBay and uBid often have characteristics that differentiate them from traditional auctions. One particularly important difference is that the number of bidders at the outset of many traditional auctions is fixed, whereas in online auctions this number and the number of resulting bids are not predetermined. The article proposes a new BARISTA (for Bid ARivals In STAges) model for describing the way in which bids arrive online. The model allows for higher bidding intensity at the outset of the auction and also as the auction comes to a close. Various properties of the model are investigated and then validated using data from eBay.com on auctions for Palm M515 personal assistants, Microsoft Xbox games, and Cartier watches. • “Statistical Challenges in the Analysis of Cosmic Microwave Background Radiation” (AAS, 2009: 61–95): The cosmic microwave background (CMB) is a significant source of information about the early history of the universe. Its radiation level is uniform, so extremely delicate instruments have been developed to measure fluctuations. The authors provide a review of statistical issues with CMB data analysis; they also give many examples of the application of statistical procedures to data obtained from a recent NASA satellite mission, the Wilkinson Microwave Anisotropy Probe. Statistical information now appears with increasing frequency in the popular media, and occasionally the spotlight is even turned on statisticians. For example, the Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.1 Populations, Samples, and Processes 9 Nov. 23, 2009, New York Times reported in an article “Behind Cancer Guidelines, Quest for Data” that the new science for cancer investigations and more sophisticated methods for data analysis spurred the U.S. Preventive Services task force to re-examine guidelines for how frequently middle-aged and older women should have mammograms. The panel commissioned six independent groups to do statistical modeling. The result was a new set of conclusions, including an assertion that mammograms every two years are nearly as beneficial to patients as annual mammograms, but confer only half the risk of harms. Donald Berry, a very prominent biostatistician, was quoted as saying he was pleasantly surprised that the task force took the new research to heart in making its recommendations. The task force’s report has generated much controversy among cancer organizations, politicians, and women themselves. It is our hope that you will become increasingly convinced of the importance and relevance of the discipline of statistics as you dig more deeply into the book and the subject. Hopefully you’ll be turned on enough to want to continue your statistical education beyond your current course. Enumerative Versus Analytic Studies W. E. Deming, a very influential American statistician who was a moving force in Japan’s quality revolution during the 1950s and 1960s, introduced the distinction between enumerative studies and analytic studies. In the former, interest is focused on a finite, identifiable, unchanging collection of individuals or objects that make up a population. A sampling frame—that is, a listing of the individuals or objects to be sampled—is either available to an investigator or else can be constructed. For example, the frame might consist of all signatures on a petition to qualify a certain initiative for the ballot in an upcoming election; a sample is usually selected to ascertain whether the number of valid signatures exceeds a specified value. As another example, the frame may contain serial numbers of all furnaces manufactured by a particular company during a certain time period; a sample may be selected to infer something about the average lifetime of these units. The use of inferential methods to be developed in this book is reasonably noncontroversial in such settings (though statisticians may still argue over which particular methods should be used). An analytic study is broadly defined as one that is not enumerative in nature. Such studies are often carried out with the objective of improving a future product by taking action on a process of some sort (e.g., recalibrating equipment or adjusting the level of some input such as the amount of a catalyst). Data can often be obtained only on an existing process, one that may differ in important respects from the future process. There is thus no sampling frame listing the individuals or objects of interest. For example, a sample of five turbines with a new design may be experimentally manufactured and tested to investigate efficiency. These five could be viewed as a sample from the conceptual population of all prototypes that could be manufactured under similar conditions, but not necessarily as representative of the population of units manufactured once regular production gets underway. Methods for using sample information to draw conclusions about future production units may be problematic. Someone with expertise in the area of turbine design and engineering (or whatever other subject area is relevant) should be called upon to judge whether such extrapolation is sensible. A good exposition of these issues is contained in the article “Assumptions for Statistical Inference” by Gerald Hahn and William Meeker (The American Statistician, 1993: 1–11). Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 10 CHAPTER 1 Overview and Descriptive Statistics Collecting Data Statistics deals not only with the organization and analysis of data once it has been collected but also with the development of techniques for collecting the data. If data is not properly collected, an investigator may not be able to answer the questions under consideration with a reasonable degree of confidence. One common problem is that the target population—the one about which conclusions are to be drawn—may be different from the population actually sampled. For example, advertisers would like various kinds of information about the television-viewing habits of potential customers. The most systematic information of this sort comes from placing monitoring devices in a small number of homes across the United States. It has been conjectured that placement of such devices in and of itself alters viewing behavior, so that characteristics of the sample may be different from those of the target population. When data collection entails selecting individuals or objects from a frame, the simplest method for ensuring a representative selection is to take a simple random sample. This is one for which any particular subset of the specified size (e.g., a sample of size 100) has the same chance of being selected. For example, if the frame consists of 1,000,000 serial numbers, the numbers 1, 2, . . . , up to 1,000,000 could be placed on identical slips of paper. After placing these slips in a box and thoroughly mixing, slips could be drawn one by one until the requisite sample size has been obtained. Alternatively (and much to be preferred), a table of random numbers or a computer’s random number generator could be employed. Sometimes alternative sampling methods can be used to make the selection process easier, to obtain extra information, or to increase the degree of confidence in conclusions. One such method, stratified sampling, entails separating the population units into nonoverlapping groups and taking a sample from each one. For example, a manufacturer of DVD players might want information about customer satisfaction for units produced during the previous year. If three different models were manufactured and sold, a separate sample could be selected from each of the three corresponding strata. This would result in information on all three models and ensure that no one model was over- or underrepresented in the entire sample. Frequently a “convenience” sample is obtained by selecting individuals or objects without systematic randomization. As an example, a collection of bricks may be stacked in such a way that it is extremely difficult for those in the center to be selected. If the bricks on the top and sides of the stack were somehow different from the others, resulting sample data would not be representative of the population. Often an investigator will assume that such a convenience sample approximates a random sample, in which case a statistician’s repertoire of inferential methods can be used; however, this is a judgment call. Most of the methods discussed herein are based on a variation of simple random sampling described in Chapter 5. Engineers and scientists often collect data by carrying out some sort of designed experiment. This may involve deciding how to allocate several different treatments (such as fertilizers or coatings for corrosion protection) to the various experimental units (plots of land or pieces of pipe). Alternatively, an investigator may systematically vary the levels or categories of certain factors (e.g., pressure or type of insulating material) and observe the effect on some response variable (such as yield from a production process). Example 1.4 An article in the New York Times (Jan. 27, 1987) reported that heart attack risk could be reduced by taking aspirin. This conclusion was based on a designed experiment involving both a control group of individuals that took a placebo having the appearance of aspirin but known to be inert and a treatment group that took aspirin Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.1 Populations, Samples, and Processes 11 according to a specified regimen. Subjects were randomly assigned to the groups to protect against any biases and so that probability-based methods could be used to analyze the data. Of the 11,034 individuals in the control group, 189 subsequently experienced heart attacks, whereas only 104 of the 11,037 in the aspirin group had a heart attack. The incidence rate of heart attacks in the treatment group was only about half that in the control group. One possible explanation for this result is chance variation—that aspirin really doesn’t have the desired effect and the observed difference is just typical variation in the same way that tossing two identical coins would usually produce different numbers of heads. However, in this case, inferential methods suggest that chance variation by itself cannot adequately explain the magnitude of the observed difference. ■ Example 1.5 An engineer wishes to investigate the effects of both adhesive type and conductor material on bond strength when mounting an integrated circuit (IC) on a certain substrate. Two adhesive types and two conductor materials are under consideration. Two observations are made for each adhesive-type/conductor-material combination, resulting in the accompanying data: Adhesive Type Conductor Material Observed Bond Strength Average 1 1 2 2 1 2 1 2 82, 77 75, 87 84, 80 78, 90 79.5 81.0 82.0 84.0 The resulting average bond strengths are pictured in Figure 1.3. It appears that adhesive type 2 improves bond strength as compared with type 1 by about the same amount whichever one of the conducting materials is used, with the 2, 2 combination being best. Inferential methods can again be used to judge whether these effects are real or simply due to chance variation. Average strength 85 Adhesive type 2 Adhesive type 1 80 1 Figure 1.3 2 Conducting material Average bond strengths in Example 1.5 Suppose additionally that there are two cure times under consideration and also two types of IC post coating. There are then 2 ? 2 ? 2 ? 2 5 16 combinations of these four factors, and our engineer may not have enough resources to make even a single observation for each of these combinations. In Chapter 11, we will see how the careful selection of a fraction of these possibilities will usually yield the desired information. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 12 CHAPTER 1 Overview and Descriptive Statistics EXERCISES Section 1.1 (1–9) 1. Give one possible sample of size 4 from each of the following populations: a. All daily newspapers published in the United States b. All companies listed on the New York Stock Exchange c. All students at your college or university d. All grade point averages of students at your college or university 2. For each of the following hypothetical populations, give a plausible sample of size 4: a. All distances that might result when you throw a football b. Page lengths of books published 5 years from now c. All possible earthquake-strength measurements (Richter scale) that might be recorded in California during the next year d. All possible yields (in grams) from a certain chemical reaction carried out in a laboratory 3. Consider the population consisting of all computers of a certain brand and model, and focus on whether a computer needs service while under warranty. a. Pose several probability questions based on selecting a sample of 100 such computers. b. What inferential statistics question might be answered by determining the number of such computers in a sample of size 100 that need warranty service? 4. a. Give three different examples of concrete populations and three different examples of hypothetical populations. b. For one each of your concrete and your hypothetical populations, give an example of a probability question and an example of an inferential statistics question. 5. Many universities and colleges have instituted supplemental instruction (SI) programs, in which a student facilitator meets regularly with a small group of students enrolled in the course to promote discussion of course material and enhance subject mastery. Suppose that students in a large statistics course (what else?) are randomly divided into a control group that will not participate in SI and a treatment group that will participate. At the end of the term, each student’s total score in the course is determined. a. Are the scores from the SI group a sample from an existing population? If so, what is it? If not, what is the relevant conceptual population? b. What do you think is the advantage of randomly dividing the students into the two groups rather than letting each student choose which group to join? c. Why didn’t the investigators put all students in the treatment group? Note: The article “Supplemental Instruction: An Effective Component of Student Affairs Programming” (J. of College Student Devel., 1997: 577–586) discusses the analysis of data from several SI programs. 6. The California State University (CSU) system consists of 23 campuses, from San Diego State in the south to Humboldt State near the Oregon border. A CSU administrator wishes to make an inference about the average distance between the hometowns of students and their campuses. Describe and discuss several different sampling methods that might be employed. Would this be an enumerative or an analytic study? Explain your reasoning. 7. A certain city divides naturally into ten district neighborhoods. How might a real estate appraiser select a sample of singlefamily homes that could be used as a basis for developing an equation to predict appraised value from characteristics such as age, size, number of bathrooms, distance to the nearest school, and so on? Is the study enumerative or analytic? 8. The amount of flow through a solenoid valve in an automobile’s pollution-control system is an important characteristic. An experiment was carried out to study how flow rate depended on three factors: armature length, spring load, and bobbin depth. Two different levels (low and high) of each factor were chosen, and a single observation on flow was made for each combination of levels. a. The resulting data set consisted of how many observations? b. Is this an enumerative or analytic study? Explain your reasoning. 9. In a famous experiment carried out in 1882, Michelson and Newcomb obtained 66 observations on the time it took for light to travel between two locations in Washington, D.C. A few of the measurements (coded in a certain manner) were 31, 23, 32, 36, 22, 26, 27, and 31. a. Why are these measurements not identical? b. Is this an enumerative study? Why or why not? 1.2 Pictorial and Tabular Methods in Descriptive Statistics Descriptive statistics can be divided into two general subject areas. In this section, we consider representing a data set using visual techniques. In Sections 1.3 and 1.4, we will develop some numerical summary measures for data sets. Many visual techniques may already be familiar to you: frequency tables, tally sheets, histograms, pie charts, Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.2 Pictorial and Tabular Methods in Descriptive Statistics 13 bar graphs, scatter diagrams, and the like. Here we focus on a selected few of these techniques that are most useful and relevant to probability and inferential statistics. Notation Some general notation will make it easier to apply our methods and formulas to a wide variety of practical problems. The number of observations in a single sample, that is, the sample size, will often be denoted by n, so that n 5 4 for the sample of universities {Stanford, Iowa State, Wyoming, Rochester} and also for the sample of pH measurements {6.3, 6.2, 5.9, 6.5}. If two samples are simultaneously under consideration, either m and n or n1 and n2 can be used to denote the numbers of observations. Thus if {29.7, 31.6, 30.9} and {28.7, 29.5, 29.4, 30.3} are thermal-efficiency measurements for two different types of diesel engines, then m 5 3 and n 5 4. Given a data set consisting of n observations on some variable x, the individual observations will be denoted by x1, x2, x3, c, xn. The subscript bears no relation to the magnitude of a particular observation. Thus x1 will not in general be the smallest observation in the set, nor will xn typically be the largest. In many applications, x1 will be the first observation gathered by the experimenter, x2 the second, and so on. The ith observation in the data set will be denoted by xi. Stem-and-Leaf Displays Consider a numerical data set x1, x2, c, xn for which each xi consists of at least two digits. A quick way to obtain an informative visual representation of the data set is to construct a stem-and-leaf display. Constructing a Stem-and-Leaf Display 1. Select one or more leading digits for the stem values. The trailing digits become the leaves. 2. List possible stem values in a vertical column. 3. Record the leaf for each observation beside the corresponding stem value. 4. Indicate the units for stems and leaves someplace in the display. If the data set consists of exam scores, each between 0 and 100, the score of 83 would have a stem of 8 and a leaf of 3. For a data set of automobile fuel efficiencies (mpg), all between 8.1 and 47.8, we could use the tens digit as the stem, so 32.6 would then have a leaf of 2.6. In general, a display based on between 5 and 20 stems is recommended. Example 1.6 The use of alcohol by college students is of great concern not only to those in the academic community but also, because of potential health and safety consequences, to society at large. The article “Health and Behavioral Consequences of Binge Drinking in College” (J. of the Amer. Med. Assoc., 1994: 1672–1677) reported on a comprehensive study of heavy drinking on campuses across the United States. A binge episode was defined as five or more drinks in a row for males and four or more for females. Figure 1.4 shows a stem-and-leaf display of 140 values of x 5 the percentage of undergraduate students who are binge drinkers. (These values were not given in the cited article, but our display agrees with a picture of the data that did appear.) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 14 CHAPTER 1 Overview and Descriptive Statistics 0 1 2 3 4 5 6 4 1345678889 1223456666777889999 0112233344555666677777888899999 111222223344445566666677788888999 00111222233455666667777888899 01111244455666778 Stem: tens digit Leaf: ones digit Figure 1.4 Stem-and-leaf display for the percentage of binge drinkers at each of the 140 colleges The first leaf on the stem 2 row is 1, which tells us that 21% of the students at one of the colleges in the sample were binge drinkers. Without the identification of stem digits and leaf digits on the display, we wouldn’t know whether the stem 2, leaf 1 observation should be read as 21%, 2.1%, or .21%. When creating a display by hand, ordering the leaves from smallest to largest on each line can be time-consuming. This ordering usually contributes little if any extra information. Suppose the observations had been listed in alphabetical order by school name, as 16% 33% 64% 37% 31% c Then placing these values on the display in this order would result in the stem 1 row having 6 as its first leaf, and the beginning of the stem 3 row would be 3 u 371 c The display suggests that a typical or representative value is in the stem 4 row, perhaps in the mid-40% range. The observations are not highly concentrated about this typical value, as would be the case if all values were between 20% and 49%. The display rises to a single peak as we move downward, and then declines; there are no gaps in the display. The shape of the display is not perfectly symmetric, but instead appears to stretch out a bit more in the direction of low leaves than in the direction of high leaves. Lastly, there are no observations that are unusually far from the bulk of the data (no outliers), as would be the case if one of the 26% values had instead been 86%. The most surprising feature of this data is that, at most colleges in the sample, at least one-quarter of the students are binge drinkers. The problem of heavy drinking on campuses is much more pervasive than many had suspected. ■ A stem-and-leaf display conveys information about the following aspects of the data: Example 1.7 • identification of a typical or representative value • extent of spread about the typical value • presence of any gaps in the data • extent of symmetry in the distribution of values • number and location of peaks • presence of any outlying values Figure 1.5 presents stem-and-leaf displays for a random sample of lengths of golf courses (yards) that have been designated by Golf Magazine as among the most challenging in the United States. Among the sample of 40 courses, the shortest is 6433 yards long, and the longest is 7280 yards. The lengths appear to be distributed in a Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.2 Pictorial and Tabular Methods in Descriptive Statistics 15 roughly uniform fashion over the range of values in the sample. Notice that a stem choice here of either a single digit (6 or 7) or three digits (643, . . . , 728) would yield an uninformative display, the first because of too few stems and the latter because of too many. Statistical software packages do not generally produce displays with multipledigit stems. The Minitab display in Figure 1.5(b) results from truncating each observation by deleting the ones digit. 64 65 66 67 68 69 70 71 72 35 64 33 26 27 06 05 94 14 90 70 00 90 70 73 00 27 36 51 05 11 31 69 68 80 09 70 83 Stem: Thousands and hundreds digits Leaf: Tens and ones digits 98 50 04 40 05 70 45 Stem-and-leaf of yardage N 40 Leaf Unit 10 4 64 3367 8 65 0228 11 66 019 18 67 0147799 (4) 68 5779 18 69 0023 14 70 012455 8 71 013666 2 72 08 13 50 22 13 65 (b) (a) Figure 1.5 Stem-and-leaf displays of golf course lengths: (a) two-digit leaves; (b) display from Minitab with truncated one-digit leaves ■ Dotplots A dotplot is an attractive summary of numerical data when the data set is reasonably small or there are relatively few distinct data values. Each observation is represented by a dot above the corresponding location on a horizontal measurement scale. When a value occurs more than once, there is a dot for each occurrence, and these dots are stacked vertically. As with a stem-and-leaf display, a dotplot gives information about location, spread, extremes, and gaps. Example 1.8 Here is data on state-by-state appropriations for higher education as a percentage of state and local tax revenue for the fiscal year 2006–2007 (from the Statistical Abstract of the United States); values are listed in order of state abbreviations (AL first, WY last): 10.8 8.1 4.0 12.8 7.4 6.9 8.0 6.7 3.5 7.5 8.0 5.9 5.8 10.0 8.4 8.8 5.9 9.9 9.1 8.3 7.3 7.6 5.6 5.0 2.6 3.6 8.9 5.8 8.1 5.1 4.1 8.5 9.3 5.3 6.0 6.0 8.1 6.2 3.9 7.0 4.4 4.2 2.5 4.0 6.5 8.3 5.7 4.5 8.0 10.3 Figure 1.6 shows a dotplot of the data. The most striking feature is the substantial state-to-state variability. The largest value (for New Mexico) and the two smallest values (New Hampshire and Vermont) are somewhat separated from the bulk of the data, though not perhaps by enough to be considered outliers. 2.8 4.2 5.6 Figure 1.6 7.0 8.4 9.8 11.2 A dotplot of the data from Example 1.8 12.6 ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 16 CHAPTER 1 Overview and Descriptive Statistics If the number of compressive strength observations in Example 1.2 had been much larger than the n 5 27 actually obtained, it would be quite cumbersome to construct a dotplot. Our next technique is well suited to such situations. Histograms Some numerical data is obtained by counting to determine the value of a variable (the number of traffic citations a person received during the last year, the number of customers arriving for service during a particular period), whereas other data is obtained by taking measurements (weight of an individual, reaction time to a particular stimulus). The prescription for drawing a histogram is generally different for these two cases. DEFINITION A numerical variable is discrete if its set of possible values either is finite or else can be listed in an infinite sequence (one in which there is a first number, a second number, and so on). A numerical variable is continuous if its possible values consist of an entire interval on the number line. A discrete variable x almost always results from counting, in which case possible values are 0, 1, 2, 3, . . . or some subset of these integers. Continuous variables arise from making measurements. For example, if x is the pH of a chemical substance, then in theory x could be any number between 0 and 14: 7.0, 7.03, 7.032, and so on. Of course, in practice there are limitations on the degree of accuracy of any measuring instrument, so we may not be able to determine pH, reaction time, height, and concentration to an arbitrarily large number of decimal places. However, from the point of view of creating mathematical models for distributions of data, it is helpful to imagine an entire continuum of possible values. Consider data consisting of observations on a discrete variable x. The frequency of any particular x value is the number of times that value occurs in the data set. The relative frequency of a value is the fraction or proportion of times the value occurs: relative frequency of a value 5 number of times the value occurs number of observations in the data set Suppose, for example, that our data set consists of 200 observations on x 5 the number of courses a college student is taking this term. If 70 of these x values are 3, then frequency of the x value 3: 70 relative frequency of the x value 3: 70 5 .35 200 Multiplying a relative frequency by 100 gives a percentage; in the college-course example, 35% of the students in the sample are taking three courses. The relative frequencies, or percentages, are usually of more interest than the frequencies themselves. In theory, the relative frequencies should sum to 1, but in practice the sum may differ slightly from 1 because of rounding. A frequency distribution is a tabulation of the frequencies and/or relative frequencies. Constructing a Histogram for Discrete Data First, determine the frequency and relative frequency of each x value. Then mark possible x values on a horizontal scale. Above each value, draw a rectangle whose height is the relative frequency (or alternatively, the frequency) of that value. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.2 Pictorial and Tabular Methods in Descriptive Statistics 17 This construction ensures that the area of each rectangle is proportional to the relative frequency of the value. Thus if the relative frequencies of x 5 1 and x 5 5 are .35 and .07, respectively, then the area of the rectangle above 1 is five times the area of the rectangle above 5. Example 1.9 How unusual is a no-hitter or a one-hitter in a major league baseball game, and how frequently does a team get more than 10, 15, or even 20 hits? Table 1.1 is a frequency distribution for the number of hits per team per game for all nine-inning games that were played between 1989 and 1993. Table 1.1 Frequency Distribution for Hits in Nine-Inning Games Hits/Game 0 1 2 3 4 5 6 7 8 9 10 11 12 13 Number of Games Relative Frequency Hits/Game 20 72 209 527 1048 1457 1988 2256 2403 2256 1967 1509 1230 834 .0010 .0037 .0108 .0272 .0541 .0752 .1026 .1164 .1240 .1164 .1015 .0779 .0635 .0430 14 15 16 17 18 19 20 21 22 23 24 25 26 27 Number of Games Relative Frequency 569 393 253 171 97 53 31 19 13 5 1 0 1 1 .0294 .0203 .0131 .0088 .0050 .0027 .0016 .0010 .0007 .0003 .0001 .0000 .0001 .0001 19,383 1.0005 The corresponding histogram in Figure 1.7 rises rather smoothly to a single peak and then declines. The histogram extends a bit more on the right (toward large values) than it does on the left—a slight “positive skew.” Relative frequency .10 .05 0 Hits/game 0 10 Figure 1.7 20 Histogram of number of hits per nine-inning game Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 18 CHAPTER 1 Overview and Descriptive Statistics Either from the tabulated information or from the histogram itself, we can determine the following: relative relative relative proportion of games with 5 frequency 1 frequency 1 frequency for x 5 0 for x 5 1 for x 5 2 at most two hits 5 .0010 1 .0037 1 .0108 5 .0155 Similarly, proportion of games with 5 .0752 1 .1026 1 c 1 .1015 5 .6361 between 5 and 10 hits (inclusive) That is, roughly 64% of all these games resulted in between 5 and 10 (inclusive) hits. ■ Constructing a histogram for continuous data (measurements) entails subdividing the measurement axis into a suitable number of class intervals or classes, such that each observation is contained in exactly one class. Suppose, for example, that we have 50 observations on x 5 fuel efficiency of an automobile (mpg), the smallest of which is 27.8 and the largest of which is 31.4. Then we could use the class boundaries 27.5, 28.0, 28.5, . . . , and 31.5 as shown here: 27.5 28.0 28.5 29.0 29.5 30.0 30.5 31.0 31.5 One potential difficulty is that occasionally an observation lies on a class boundary so therefore does not fall in exactly one interval, for example, 29.0. One way to deal with this problem is to use boundaries like 27.55, 28.05, . . . , 31.55. Adding a hundredths digit to the class boundaries prevents observations from falling on the resulting boundaries. Another approach is to use the classes 27.52, 28.0, 28.02, 28.5, c, 31.02, 31.5 . Then 29.0 falls in the class 29.02, 29.5 rather than in the class 28.52, 29.0. In other words, with this convention, an observation on a boundary is placed in the interval to the right of the boundary. This is how Minitab constructs a histogram. Constructing a Histogram for Continuous Data: Equal Class Widths Determine the frequency and relative frequency for each class. Mark the class boundaries on a horizontal measurement axis. Above each class interval, draw a rectangle whose height is the corresponding relative frequency (or frequency). Example 1.10 Power companies need information about customer usage to obtain accurate forecasts of demands. Investigators from Wisconsin Power and Light determined energy consumption (BTUs) during a particular period for a sample of 90 gas-heated homes. An adjusted consumption value was calculated as follows: adjusted consumption 5 consumption (weather, in degree days)(house area) This resulted in the accompanying data (part of the stored data set FURNACE.MTW available in Minitab), which we have ordered from smallest to largest. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.2 Pictorial and Tabular Methods in Descriptive Statistics 2.97 6.80 7.73 8.61 9.60 10.28 11.12 12.31 13.47 4.00 6.85 7.87 8.67 9.76 10.30 11.21 12.62 13.60 5.20 6.94 7.93 8.69 9.82 10.35 11.29 12.69 13.96 5.56 7.15 8.00 8.81 9.83 10.36 11.43 12.71 14.24 5.94 7.16 8.26 9.07 9.83 10.40 11.62 12.91 14.35 5.98 7.23 8.29 9.27 9.84 10.49 11.70 12.92 15.12 6.35 7.29 8.37 9.37 9.96 10.50 11.70 13.11 15.24 6.62 7.62 8.47 9.43 10.04 10.64 12.16 13.38 16.06 6.72 7.62 8.54 9.52 10.21 10.95 12.19 13.42 16.90 19 6.78 7.69 8.58 9.58 10.28 11.09 12.28 13.43 18.26 We let Minitab select the class intervals. The most striking feature of the histogram in Figure 1.8 is its resemblance to a bell-shaped (and therefore symmetric) curve, with the point of symmetry roughly at 10. 12,3 32,5 52,7 72,9 92,11 112,13 132,15 152,17 172,19 Class Frequency 1 1 11 21 25 17 9 4 1 Relative .011 .011 .122 .233 .278 .189 .100 .044 .011 frequency 30 Percent 20 10 0 1 Figure 1.8 3 5 7 9 11 13 15 17 19 BTUIN Histogram of the energy consumption data from Example 1.10 From the histogram, 34 proportion of 5 .378) < .01 1 .01 1 .12 1 .23 5 .37 (exact value 5 observations 90 less than 9 The relative frequency for the 92,11 class is about .27, so we estimate that roughly half of this, or .135, is between 9 and 10. Thus proportion of observations < .37 1 .135 5 .505 (slightly more than 50%) less than 10 The exact value of this proportion is 47/90 5 .522. ■ There are no hard-and-fast rules concerning either the number of classes or the choice of classes themselves. Between 5 and 20 classes will be satisfactory for most data sets. Generally, the larger the number of observations in a data set, the more classes should be used. A reasonable rule of thumb is number of classes < 1number of observations Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 20 CHAPTER 1 Overview and Descriptive Statistics Equal-width classes may not be a sensible choice if there are some regions of the measurement scale that have a high concentration of data values and other parts where data is quite sparse. Figure 1.9 shows a dotplot of such a data set; there is high concentration in the middle, and relatively few observations stretched out to either side. Using a small number of equal-width classes results in almost all observations falling in just one or two of the classes. If a large number of equal-width classes are used, many classes will have zero frequency. A sound choice is to use a few wider intervals near extreme observations and narrower intervals in the region of high concentration. (a) (b) (c) Figure 1.9 Selecting class intervals for “varying density” data: (a) many short equal-width intervals; (b) a few wide equal-width intervals; (c) unequal-width intervals Constructing a Histogram for Continuous Data: Unequal Class Widths After determining frequencies and relative frequencies, calculate the height of each rectangle using the formula rectangle height 5 relative frequency of the class class width The resulting rectangle heights are usually called densities, and the vertical scale is the density scale. This prescription will also work when class widths are equal. Example 1.11 Corrosion of reinforcing steel is a serious problem in concrete structures located in environments affected by severe weather conditions. For this reason, researchers have been investigating the use of reinforcing bars made of composite material. One study was carried out to develop guidelines for bonding glass-fiber-reinforced plastic rebars to concrete (“Design Recommendations for Bond of GFRP Rebars to Concrete,” J. of Structural Engr., 1996: 247–254). Consider the following 48 observations on measured bond strength: 11.5 5.7 3.6 5.2 12.1 5.4 3.4 5.5 Class Frequency Relative frequency Density 9.9 5.2 20.6 5.1 9.3 5.1 25.5 5.0 22,4 9 .1875 .094 7.8 4.9 13.8 5.2 42,6 15 .3125 .156 6.2 10.7 12.6 4.8 6.6 15.2 13.1 4.1 62,8 5 .1042 .052 7.0 8.5 8.9 3.8 82,12 9 .1875 .047 13.4 4.2 8.2 3.7 17.1 4.0 10.7 3.6 122,20 8 .1667 .021 9.3 3.9 14.2 3.6 5.6 3.8 7.6 3.6 202,30 2 .0417 .004 The resulting histogram appears in Figure 1.10. The right or upper tail stretches out much farther than does the left or lower tail—a substantial departure from symmetry. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.2 Pictorial and Tabular Methods in Descriptive Statistics 21 Density 0.15 0.10 0.05 0.00 2 4 6 8 Figure 1.10 12 20 Bond strength 30 A Minitab density histogram for the bond strength data of Example 1.11 ■ When class widths are unequal, not using a density scale will give a picture with distorted areas. For equal-class widths, the divisor is the same in each density calculation, and the extra arithmetic simply results in a rescaling of the vertical axis (i.e., the histogram using relative frequency and the one using density will have exactly the same appearance). A density histogram does have one interesting property. Multiplying both sides of the formula for density by the class width gives relative frequency 5 (class width)(density) 5 (rectangle width)(rectangle height) 5 rectangle area That is, the area of each rectangle is the relative frequency of the corresponding class. Furthermore, since the sum of relative frequencies should be 1, the total area of all rectangles in a density histogram is l. It is always possible to draw a histogram so that the area equals the relative frequency (this is true also for a histogram of discrete data)—just use the density scale. This property will play an important role in creating models for distributions in Chapter 4. Histogram Shapes Histograms come in a variety of shapes. A unimodal histogram is one that rises to a single peak and then declines. A bimodal histogram has two different peaks. Bimodality can occur when the data set consists of observations on two quite different kinds of individuals or objects. For example, consider a large data set consisting of driving times for automobiles traveling between San Luis Obispo, California, and Monterey, California (exclusive of stopping time for sightseeing, eating, etc.). This histogram would show two peaks: one for those cars that took the inland route (roughly 2.5 hours) and another for those cars traveling up the coast (3.5–4 hours). However, bimodality does not automatically follow in such situations. Only if the two separate histograms are “far apart” relative to their spreads will bimodality occur in the histogram of combined data. Thus a large data set consisting of heights of college students should not result in a bimodal histogram because the typical male height of about 69 inches is not far enough above the typical female height of about 64–65 inches. A histogram with more than two peaks is said to be multimodal. Of course, the number of peaks may well depend on the choice of class intervals, particularly with a small number of observations. The larger the number of classes, the more likely it is that bimodality or multimodality will manifest itself. Example 1.12 Figure 1.11(a) shows a Minitab histogram of the weights (lb) of the 124 players listed on the rosters of the San Francisco 49ers and the New England Patriots (teams the author would like to see meet in the Super Bowl) as of Nov. 20, 2009. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 22 CHAPTER 1 Overview and Descriptive Statistics Figure 1.11(b) is a smoothed histogram (actually what is called a density estimate) of the data from the R software package. Both the histogram and the smoothed histogram show three distinct peaks; the one on the right is for linemen, the middle peak corresponds to linebacker weights, and the peak on the left is for all other players (wide receivers, quarterbacks, etc.). 14 12 Percent 10 8 6 4 2 0 220 200 240 260 Weight (a) 280 300 320 340 Density Estimate 0.000 0.002 0.004 0.006 0.008 0.010 0.012 180 150 Figure 1.11 200 250 Player Weight (b) 300 350 ■ NFL player weights (a) Histogram (b) Smoothed histogram A histogram is symmetric if the left half is a mirror image of the right half. A unimodal histogram is positively skewed if the right or upper tail is stretched out compared with the left or lower tail and negatively skewed if the stretching is to the left. Figure 1.12 shows “smoothed” histograms, obtained by superimposing a smooth curve on the rectangles, that illustrate the various possibilities. (a) (b) (c) (d) Figure 1.12 Smoothed histograms: (a) symmetric unimodal; (b) bimodal; (c) positively skewed; and (d) negatively skewed Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.2 Pictorial and Tabular Methods in Descriptive Statistics 23 Qualitative Data Both a frequency distribution and a histogram can be constructed when the data set is qualitative (categorical) in nature. In some cases, there will be a natural ordering of classes—for example, freshmen, sophomores, juniors, seniors, graduate students— whereas in other cases the order will be arbitrary—for example, Catholic, Jewish, Protestant, and the like. With such categorical data, the intervals above which rectangles are constructed should have equal width. Example 1.13 The Public Policy Institute of California carried out a telephone survey of 2501 California adult residents during April 2006 to ascertain how they felt about various aspects of K-12 public education. One question asked was “Overall, how would you rate the quality of public schools in your neighborhood today?” Table 1.2 displays the frequencies and relative frequencies, and Figure 1.13 shows the corresponding histogram (bar chart). Table 1.2 Frequency Distribution for the School Rating Data Rating Frequency Relative Frequency A B C D F Don’t know 478 893 680 178 100 172 .191 .357 .272 .071 .040 .069 2501 1.000 Chart of Relative Frequency vs Rating Relative Frequency 0.4 0.3 0.2 0.1 0.0 A B C D F Don’t know Rating Figure 1.13 Histogram of the school rating data from Minitab More than half the respondents gave an A or B rating, and only slightly more than 10% gave a D or F rating. The percentages for parents of public school children were somewhat more favorable to schools: 24%, 40%, 24%, 6%, 4%, and 2%. ■ Multivariate Data Multivariate data is generally rather difficult to describe visually. Several methods for doing so appear later in the book, notably scatter plots for bivariate numerical data. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 24 CHAPTER 1 Overview and Descriptive Statistics EXERCISES Section 1.2 (10–32) 10. Consider the strength data for beams given in Example 1.2. a. Construct a stem-and-leaf display of the data. What appears to be a representative strength value? Do the observations appear to be highly concentrated about the representative value or rather spread out? b. Does the display appear to be reasonably symmetric about a representative value, or would you describe its shape in some other way? c. Do there appear to be any outlying strength values? d. What proportion of strength observations in this sample exceed 10 MPa? 11. Every score in the following batch of exam scores is in the 60s, 70s, 80s, or 90s. A stem-and-leaf display with only the four stems 6, 7, 8, and 9 would not give a very detailed description of the distribution of scores. In such situations, it is desirable to use repeated stems. Here we could repeat the stem 6 twice, using 6L for scores in the low 60s (leaves 0, 1, 2, 3, and 4) and 6H for scores in the high 60s (leaves 5, 6, 7, 8, and 9). Similarly, the other stems can be repeated twice to obtain a display consisting of eight rows. Construct such a display for the given scores. What feature of the data is highlighted by this display? 74 89 80 93 64 67 72 70 66 85 89 81 81 71 74 82 85 63 72 81 81 95 84 81 80 70 69 66 60 83 85 98 84 68 90 82 69 72 87 88 12. The accompanying specific gravity values for various wood types used in construction appeared in the article “Bolted Connection Design Values Based on European Yield Model” (J. of Structural Engr., 1993: 2169–2186): .31 .41 .45 .54 .35 .41 .46 .55 .36 .42 .46 .58 .36 .42 .47 .62 .37 .42 .48 .66 .38 .42 .48 .66 .40 .42 .48 .67 .40 .43 .51 .68 .40 .44 .54 .75 Construct a stem-and-leaf display using repeated stems (see the previous exercise), and comment on any interesting features of the display. 13. Allowable mechanical properties for structural design of metallic aerospace vehicles requires an approved method for statistically analyzing empirical test data. The article “Establishing Mechanical Property Allowables for Metals” (J. of Testing and Evaluation, 1998: 293–299) used the accompanying data on tensile ultimate strength (ksi) as a basis for addressing the difficulties in developing such a method. 122.2 127.5 130.4 131.8 124.2 127.9 130.8 132.3 124.3 128.6 131.3 132.4 125.6 128.8 131.4 132.4 126.3 129.0 131.4 132.5 126.5 129.2 131.5 132.5 126.5 129.4 131.6 132.5 127.2 129.6 131.6 132.5 127.3 130.2 131.8 132.6 132.7 133.2 134.0 134.7 135.2 135.7 135.9 136.6 137.8 138.4 139.1 140.9 143.6 132.9 133.3 134.0 134.7 135.2 135.8 136.0 136.8 137.8 138.4 139.5 140.9 143.8 133.0 133.3 134.0 134.7 135.3 135.8 136.0 136.9 137.8 138.4 139.6 141.2 143.8 133.1 133.5 134.1 134.8 135.3 135.8 136.1 136.9 137.9 138.5 139.8 141.4 143.9 133.1 133.5 134.2 134.8 135.4 135.8 136.2 137.0 137.9 138.5 139.8 141.5 144.1 133.1 133.5 134.3 134.8 135.5 135.8 136.2 137.1 138.2 138.6 140.0 141.6 144.5 133.1 133.8 134.4 134.9 135.5 135.9 136.3 137.2 138.2 138.7 140.0 142.9 144.5 133.2 133.9 134.4 134.9 135.6 135.9 136.4 137.6 138.3 138.7 140.7 143.4 147.7 133.2 134.0 134.6 135.2 135.6 135.9 136.4 137.6 138.3 139.0 140.7 143.5 147.7 a. Construct a stem-and-leaf display of the data by first deleting (truncating) the tenths digit and then repeating each stem value five times (once for leaves 1 and 2, a second time for leaves 3 and 4, etc.). Why is it relatively easy to identify a representative strength value? b. Construct a histogram using equal-width classes with the first class having a lower limit of 122 and an upper limit of 124. Then comment on any interesting features of the histogram. 14. The accompanying data set consists of observations on shower-flow rate (L/min) for a sample of n 5 129 houses in Perth, Australia (“An Application of Bayes Methodology to the Analysis of Diary Records in a Water Use Study,” J. Amer. Stat. Assoc., 1987: 705–711): 4.6 12.3 11.2 10.5 7.5 6.2 8.3 6.5 5.4 4.8 7.6 3.9 5.4 5.5 8.4 7.3 5.1 6.7 10.8 15.5 7.8 7.0 9.3 9.6 8.3 3.2 7.1 7.0 4.0 14.3 8.0 8.8 5.8 2.3 3.4 7.6 9.3 9.2 7.5 6.0 6.9 11.9 2.2 15.0 4.3 9.0 12.7 10.3 11.9 6.0 10.2 6.2 8.4 7.5 6.4 3.4 6.9 4.1 3.6 10.4 9.3 6.9 4.9 5.0 6.0 9.2 6.4 10.4 7.3 10.8 7.2 11.3 5.6 7.0 5.5 11.9 9.8 8.2 6.7 6.9 11.5 5.1 5.1 5.6 9.6 7.5 9.8 6.6 3.7 6.4 5.0 6.3 13.8 6.2 7.5 6.6 5.0 3.3 6.1 15.3 18.9 7.2 7.4 5.0 3.5 8.2 9.5 9.3 10.4 9.7 4.8 5.6 10.5 14.6 6.6 5.9 15.0 9.6 3.7 5.7 6.8 11.3 9.1 10.6 4.5 6.2 6.3 3.8 6.0 a. Construct a stem-and-leaf display of the data. b. What is a typical, or representative, flow rate? c. Does the display appear to be highly concentrated or spread out? d. Does the distribution of values appear to be reasonably symmetric? If not, how would you describe the departure from symmetry? e. Would you describe any observation as being far from the rest of the data (an outlier)? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.2 Pictorial and Tabular Methods in Descriptive Statistics 15. Do running times of American movies differ somehow from running times of French movies? The author investigated this question by randomly selecting 25 recent movies of each type, resulting in the following running times: Am: 94 110 Fr: 123 106 90 92 116 95 95 113 90 125 93 116 158 122 128 90 122 103 95 97 119 96 125 103 125 111 91 104 95 120 90 96 81 113 116 109 94 128 162 91 137 93 102 90 138 102 105 92 Construct a comparative stem-and-leaf display by listing stems in the middle of your paper and then placing the Am leaves out to the left and the Fr leaves out to the right. Then comment on interesting features of the display. 16. The article cited in Example 1.2 also gave the accompanying strength observations for cylinders: 6.1 7.8 5.8 8.1 7.8 7.4 7.1 8.5 7.2 8.9 9.2 9.8 6.6 9.7 8.3 14.1 7.0 12.6 8.3 11.2 a. Construct a comparative stem-and-leaf display (see the previous exercise) of the beam and cylinder data, and then answer the questions in parts (b)–(d) of Exercise 10 for the observations on cylinders. b. In what ways are the two sides of the display similar? Are there any obvious differences between the beam observations and the cylinder observations? c. Construct a dotplot of the cylinder data. 17. Temperature transducers of a certain type are shipped in batches of 50. A sample of 60 batches was selected, and the number of transducers in each batch not conforming to design specifications was determined, resulting in the following data: 2 1 2 4 0 1 3 2 0 5 3 3 1 3 2 4 7 0 2 3 0 4 2 1 3 1 1 3 4 1 2 3 2 2 8 4 5 1 3 1 5 0 2 3 2 1 0 6 4 2 1 6 0 3 3 3 6 1 2 3 a. Determine frequencies and relative frequencies for the observed values of x 5 number of nonconforming transducers in a batch. b. What proportion of batches in the sample have at most five nonconforming transducers? What proportion have fewer than five? What proportion have at least five nonconforming units? c. Draw a histogram of the data using relative frequency on the vertical scale, and comment on its features. 18. In a study of author productivity (“Lotka’s Test,” Collection Mgmt., 1982: 111–118), a large number of authors were classified according to the number of articles they had published during a certain period. The results were presented in the accompanying frequency distribution: Number of papers Frequency Number of papers Frequency 1 2 3 4 5 6 7 8 784 204 127 50 33 28 19 19 9 6 10 11 7 6 12 13 7 4 14 15 16 17 4 5 3 3 25 a. Construct a histogram corresponding to this frequency distribution. What is the most interesting feature of the shape of the distribution? b. What proportion of these authors published at least five papers? At least ten papers? More than ten papers? c. Suppose the five 15s, three 16s, and three 17s had been lumped into a single category displayed as “$15.” Would you be able to draw a histogram? Explain. d. Suppose that instead of the values 15, 16, and 17 being listed separately, they had been combined into a 15–17 category with frequency 11. Would you be able to draw a histogram? Explain. 19. The number of contaminating particles on a silicon wafer prior to a certain rinsing process was determined for each wafer in a sample of size 100, resulting in the following frequencies: Number of particles 0 1 2 3 Frequency 1 2 3 12 Number of particles 8 9 10 11 Frequency 12 4 5 3 4 5 6 7 11 15 18 10 12 13 14 1 2 1 a. What proportion of the sampled wafers had at least one particle? At least five particles? b. What proportion of the sampled wafers had between five and ten particles, inclusive? Strictly between five and ten particles? c. Draw a histogram using relative frequency on the vertical axis. How would you describe the shape of the histogram? 20. The article “Determination of Most Representative Subdivision” (J. of Energy Engr., 1993: 43–55) gave data on various characteristics of subdivisions that could be used in deciding whether to provide electrical power using overhead lines or underground lines. Here are the values of the variable x 5 total length of streets within a subdivision: 1280 1050 1320 960 3150 2700 510 5320 360 530 1120 5700 2730 240 4390 3330 3350 2120 5220 1670 396 2100 3380 540 450 500 100 1419 1240 340 3870 2250 1850 5770 2109 3060 1000 1250 2320 2460 3150 4770 960 2400 2400 5850 1890 a. Construct a stem-and-leaf display using the thousands digit as the stem and the hundreds digit as the leaf, and comment on the various features of the display. b. Construct a histogram using class boundaries 0, 1000, 2000, 3000, 4000, 5000, and 6000. What proportion of subdivisions have total length less than 2000? Between 2000 and 4000? How would you describe the shape of the histogram? 21. The article cited in Exercise 20 also gave the following values of the variables y 5 number of culs-de-sac and z 5 number of intersections: y 1 0 1 0 0 2 0 1 1 1 2 1 0 0 1 1 0 1 1 z 1 8 6 1 1 5 3 0 0 4 4 0 0 1 2 1 4 0 4 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 26 CHAPTER 1 Overview and Descriptive Statistics y 1 1 0 0 0 1 1 2 0 1 2 2 1 1 0 2 1 1 0 z 0 3 0 1 1 0 1 3 2 4 6 6 0 1 1 8 3 3 5 y 1 5 0 3 0 1 1 0 0 z 0 5 2 3 1 0 0 0 3 a. Construct a histogram for the y data. What proportion of these subdivisions had no culs-de-sac? At least one cul-de-sac? b. Construct a histogram for the z data. What proportion of these subdivisions had at most five intersections? Fewer than five intersections? 24. The accompanying data set consists of observations on shear strength (lb) of ultrasonic spot welds made on a certain type of alclad sheet. Construct a relative frequency histogram based on ten equal-width classes with boundaries 4000, 4200, . . . . [The histogram will agree with the one in “Comparison of Properties of Joints Prepared by Ultrasonic Welding and Other Means” (J. of Aircraft, 1983: 552–556).] Comment on its features. 5434 5112 4820 5378 5027 4848 4755 5207 5049 4740 5248 5227 4931 5364 5189 22. How does the speed of a runner vary over the course of a marathon (a distance of 42.195 km)? Consider determining both the time to run the first 5 km and the time to run between the 35-km and 40-km points, and then subtracting the former time from the latter time. A positive value of this difference corresponds to a runner slowing down toward the end of the race. The accompanying histogram is based on times of runners who participated in several different Japanese marathons (“Factors Affecting Runners’ Marathon Performance,” Chance, Fall, 1993: 24–30). What are some interesting features of this histogram? What is a typical difference value? Roughly what proportion of the runners ran the late distance more quickly than the early distance? 23. The article “Statistical Modeling of the Time Course of Tantrum Anger” (Annals of Applied Stats, 2009: 1013–1034) discussed how anger intensity in children’s tantrums could be related to tantrum duration as well as behavioral indicators such as shouting, stamping, and pushing or pulling. The following frequency distribution was given (and also the corresponding histogram): 02,2 : 112,20: 136 26 22,4: 202,30: 92 7 42,11: 302,40: 71 3 Draw the histogram and then comment on any interesting features. Histogram for Exercise 22 4948 5015 5043 5260 5008 5089 4925 5621 4974 5173 5245 5555 4493 5640 4986 4521 4659 4886 5055 4609 5518 5001 4918 4592 4568 4723 5388 5309 5069 4570 4806 4599 5828 4772 5333 4803 5138 4173 5653 5275 5498 5582 5188 4990 4637 5288 5218 5133 5164 4951 4786 5296 5078 5419 4681 4308 5764 5702 5670 5299 4859 5095 5342 5679 4500 4965 4900 5205 5076 4823 5273 5241 4381 4848 4780 4618 5069 5256 5461 5170 4968 4452 4774 4417 5042 25. A transformation of data values by means of some mathematical function, such as 1x or 1/x, can often yield a set of numbers that has “nicer” statistical properties than the original data. In particular, it may be possible to find a function for which the histogram of transformed values is more symmetric (or, even better, more like a bell-shaped curve) than the original data. As an example, the article “Time Lapse Cinematographic Analysis of Beryllium–Lung Fibroblast Interactions” (Environ. Research, 1983: 34–43) reported the results of experiments designed to study the behavior of certain individual cells that had been exposed to beryllium. An important characteristic of such an individual cell is its interdivision time (IDT). IDTs were determined for a large number of cells, both in exposed Frequency 200 150 100 50 –100 0 100 200 300 400 500 600 700 800 Time difference Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 27 1.2 Pictorial and Tabular Methods in Descriptive Statistics (treatment) and unexposed (control) conditions. The authors of the article used a logarithmic transformation, that is, transformed value 5 log(original value). Consider the following representative IDT data: IDT log10(IDT) IDT log10(IDT) IDT log10(IDT) 28.1 31.2 13.7 46.0 25.8 16.8 34.8 62.3 28.0 17.9 19.5 21.1 31.9 28.9 1.45 1.49 1.14 1.66 1.41 1.23 1.54 1.79 1.45 1.25 1.29 1.32 1.50 1.46 60.1 23.7 18.6 21.4 26.6 26.2 32.0 43.5 17.4 38.8 30.6 55.6 25.5 52.1 1.78 1.37 1.27 1.33 1.42 1.42 1.51 1.64 1.24 1.59 1.49 1.75 1.41 1.72 21.0 22.3 15.5 36.3 19.1 38.4 72.8 48.9 21.4 20.7 57.3 40.9 1.32 1.35 1.19 1.56 1.28 1.58 1.86 1.69 1.33 1.32 1.76 1.61 Use class intervals 102,20, 202,30, cto construct a histogram of the original data. Use intervals 1.12,1.2, 1.22,1.3, cto do the same for the transformed data. What is the effect of the transformation? 26. Automated electron backscattered diffraction is now being used in the study of fracture phenomena. The following information on misorientation angle (degrees) was extracted from the article “Observations on the Faceted Initiation Site in the Dwell-Fatigue Tested Ti-6242 Alloy: Crystallographic Orientation and Size Effects (Metallurgical and Materials Trans., 2006: 1507–1518). Class: Rel freq: Class: Rel freq: 02,5 .177 202,30 .194 52,10 .166 302,40 .078 102,15 .175 402,60 .044 152,20 .136 602,90 .030 a. Is it true that more than 50% of the sampled angles are smaller than 15°, as asserted in the paper? b. What proportion of the sampled angles are at least 30°? c. Roughly what proportion of angles are between 10° and 25°? d. Construct a histogram and comment on any interesting features. 27. The paper “Study on the Life Distribution of Microdrills” (J. of Engr. Manufacture, 2002: 301–305) reported the following observations, listed in increasing order, on drill lifetime (number of holes that a drill machines before it breaks) when holes were drilled in a certain brass alloy. 11 14 59 61 81 84 105 105 161 168 20 23 65 67 85 89 112 118 184 206 31 36 68 71 91 93 123 136 248 263 39 44 47 50 74 76 78 79 96 99 101 104 139 141 148 158 289 322 388 513 a. Why can a frequency distribution not be based on the class intervals 0–50, 50–100, 100–150, and so on? b. Construct a frequency distribution and histogram of the data using class boundaries 0, 50, 100, . . . , and then comment on interesting characteristics. c. Construct a frequency distribution and histogram of the natural logarithms of the lifetime observations, and comment on interesting characteristics. d. What proportion of the lifetime observations in this sample are less than 100? What proportion of the observations are at least 200? 28. Human measurements provide a rich area of application for statistical methods. The article “A Longitudinal Study of the Development of Elementary School Children’s Private Speech” (Merrill-Palmer Q., 1990: 443–463) reported on a study of children talking to themselves (private speech). It was thought that private speech would be related to IQ, because IQ is supposed to measure mental maturity, and it was known that private speech decreases as students progress through the primary grades. The study included 33 students whose first-grade IQ scores are given here: 82 96 99 102 103 103 106 107 108 108 108 108 109 110 110 111 113 113 113 113 115 115 118 118 119 121 122 122 127 132 136 140 146 Describe the data and comment on any interesting features. 29. Consider the following data on types of health complaint (J 5 joint swelling, F 5 fatigue, B 5 back pain, M 5 muscle weakness, C 5 coughing, N 5 nose running/ irritation, O 5 other) made by tree planters. Obtain frequencies and relative frequencies for the various categories, and draw a histogram. (The data is consistent with percentages given in the article “Physiological Effects of Work Stress and Pesticide Exposure in Tree Planting by British Columbia Silviculture Workers,” Ergonomics, 1993: 951–961.) O O J O J O F O F O N F J J F J O J O N C O F O F N N B B O O N B N B C F J M O O F O O J J J O O B M M O O O B M C B F 30. A Pareto diagram is a variation of a histogram for categorical data resulting from a quality control study. Each category represents a different type of product nonconformity or production problem. The categories are ordered so that the one with the largest frequency appears on the far left, then the category with the second largest frequency, and so on. Suppose the following information on nonconformities in circuit packs is obtained: failed component, 126; incorrect component, 210; insufficient solder, 67; excess solder, 54; missing component, 131. Construct a Pareto diagram. 31. The cumulative frequency and cumulative relative frequency for a particular class interval are the sum of frequencies and relative frequencies, respectively, for that interval and all intervals lying below it. If, for example, Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 28 CHAPTER 1 Overview and Descriptive Statistics there are four intervals with frequencies 9, 16, 13, and 12, then the cumulative frequencies are 9, 25, 38, and 50, and the cumulative relative frequencies are .18, .50, .76, and 1.00. Compute the cumulative frequencies and cumulative relative frequencies for the data of Exercise 24. 32. Fire load (MJ/m2) is the heat energy that could be released per square meter of floor area by combustion of contents and the structure itself. The article “Fire Loads in Office Buildings” (J. of Structural Engr., 1997: 365–368) gave the following cumulative percentages (read from a graph) for fire loads in a sample of 388 rooms: Value Cumulative % 0 0 150 19.3 300 37.6 450 62.7 600 77.5 Value Cumulative % 750 87.2 900 93.8 1050 95.7 1200 98.6 1350 99.1 Value Cumulative % 1500 99.5 1650 99.6 1800 99.8 1950 100.0 a. Construct a relative frequency histogram and comment on interesting features. b. What proportion of fire loads are less than 600? At least 1200? c. What proportion of the loads are between 600 and 1200? 1.3 Measures of Location Visual summaries of data are excellent tools for obtaining preliminary impressions and insights. More formal data analysis often requires the calculation and interpretation of numerical summary measures. That is, from the data we try to extract several summarizing numbers—numbers that might serve to characterize the data set and convey some of its salient features. Our primary concern will be with numerical data; some comments regarding categorical data appear at the end of the section. Suppose, then, that our data set is of the form x1, x2, c, xn, where each xi is a number. What features of such a set of numbers are of most interest and deserve emphasis? One important characteristic of a set of numbers is its location, and in particular its center. This section presents methods for describing the location of a data set; in Section 1.4 we will turn to methods for measuring variability in a set of numbers. The Mean For a given set of numbers x1, x2, c, xn, the most familiar and useful measure of the center is the mean, or arithmetic average of the set. Because we will almost always think of the xi’s as constituting a sample, we will often refer to the arithmetic average as the sample mean and denote it by x. DEFINITION The sample mean x of observations x1, x2, c, xn is given by n x5 x1 1 x2 1 c 1 xn 5 n g xi i51 n The numerator of x can be written more informally as gxi, where the summation is over all sample observations. For reporting x, we recommend using decimal accuracy of one digit more than the accuracy of the xi’s. Thus if observations are stopping distances with x1 5 125, x2 5 131, and so on, we might have x 5 127.3 ft. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.3 Measures of Location Example 1.14 29 Caustic stress corrosion cracking of iron and steel has been studied because of failures around rivets in steel boilers and failures of steam rotors. Consider the accompanying observations on x 5 crack length (mm) as a result of constant load stress corrosion tests on smooth bar tensile specimens for a fixed length of time. (The data is consistent with a histogram and summary quantities from the article “On the Role of Phosphorus in the Caustic Stress Corrosion Cracking of Low Alloy Steels,” Corrosion Science, 1989: 53–68.) x1 5 16.1 x2 5 9.6 x3 5 24.9 x4 5 20.4 x5 5 12.7 x6 5 21.2 x7 5 30.2 x8 5 25.8 x9 5 18.5 x10 5 10.3 x11 5 25.3 x12 5 14.0 x13 5 27.1 x14 5 45.0 x15 5 23.3 x16 5 24.2 x17 5 14.6 x18 5 8.9 x19 5 32.4 x20 5 11.8 x21 5 28.5 Figure 1.14 shows a stem-and-leaf display of the data; a crack length in the low 20s appears to be “typical.” 0H 1L 1H 2L 2H 3L 3H 4L 4H 96 89 27 03 40 46 18 61 85 49 04 12 33 42 58 53 71 85 02 24 Stem: tens digit Leaf: one and tenths digit 50 Figure 1.14 A stem-and-leaf display of the crack-length data With gxi 5 444.8, the sample mean is x5 444.8 5 21.18 21 a value consistent with information conveyed by the stem-and-leaf display. ■ A physical interpretation of x demonstrates how it measures the location (center) of a sample. Think of drawing and scaling a horizontal measurement axis, and then represent each sample observation by a 1-lb weight placed at the corresponding point on the axis. The only point at which a fulcrum can be placed to balance the system of weights is the point corresponding to the value of x (see Figure 1.15). x = 21.18 10 20 Figure 1.15 30 40 The mean as the balance point for a system of weights Just as x represents the average value of the observations in a sample, the average of all values in the population can be calculated. This average is called the population mean and is denoted by the Greek letter m. When there are N values in the population (a finite population), then m 5 (sum of the N population values)/N. In Chapters 3 and 4, we will give a more general definition for m that applies to both finite and (conceptually) infinite populations. Just as x is an interesting and important measure of sample location, m is an interesting and important (often the most important) characteristic of a population. In the chapters on statistical Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 30 CHAPTER 1 Overview and Descriptive Statistics inference, we will present methods based on the sample mean for drawing conclusions about a population mean. For example, we might use the sample mean x 5 21.18 computed in Example 1.14 as a point estimate (a single number that is our “best” guess) of m 5 the true average crack length for all specimens treated as described. The mean suffers from one deficiency that makes it an inappropriate measure of center under some circumstances: Its value can be greatly affected by the presence of even a single outlier (unusually large or small observation). In Example 1.14, the value x14 5 45.0 is obviously an outlier. Without this observation, x 5 399.8/20 5 19.99; the outlier increases the mean by more than 1 mm. If the 45.0 mm observation were replaced by the catastrophic value 295.0 mm, a really extreme outlier, then x 5 694.8/21 5 33.09, which is larger than all but one of the observations! A sample of incomes often produces such outlying values (those lucky few who earn astronomical amounts), and the use of average income as a measure of location will often be misleading. Such examples suggest that we look for a measure that is less sensitive to outlying values than x, and we will momentarily propose one. However, although x does have this potential defect, it is still the most widely used measure, largely because there are many populations for which an extreme outlier in the sample would be highly unlikely. When sampling from such a population (a normal or bell-shaped population being the most important example), the sample mean will tend to be stable and quite representative of the sample. The Median The word median is synonymous with “middle,” and the sample median is indeed the middle value once the observations are ordered from smallest to largest. When the observations are denoted by x1, c, xn, we will use the symbol | x to represent the sample median. DEFINITION The sample median is obtained by first ordering the n observations from smallest to largest (with any repeated values included so that every sample observation appears in the ordered list). Then, ⎧ The single ⎪ middle ⎪ value if n ⎪ ⎪ is odd | x 5 ⎨ The average ⎪ of the two ⎪ middle ⎪ ⎪ values if n ⎩ is even Example 1.15 5 a n 1 1 th b ordered value 2 th n th n 5 average of a b and a 1 1b ordered values 2 2 People not familiar with classical music might tend to believe that a composer’s instructions for playing a particular piece are so specific that the duration would not depend at all on the performer(s). However, there is typically plenty of room for interpretation, and orchestral conductors and musicians take full advantage of this. The author went to the Web site ArkivMusic.com and selected a sample of Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.3 Measures of Location 31 12 recordings of Beethoven’s Symphony #9 (the “Choral,” a stunningly beautiful work), yielding the following durations (min) listed in increasing order: 62.3 62.8 63.6 65.2 65.7 66.4 67.4 68.4 68.8 70.8 75.7 79.0 Here is a dotplot of the data: 60 65 70 Duration Figure 1.16 75 80 Dotplot of the data from Example 1.14 Since n 5 12 is even, the sample median is the average of the n/2 5 6th and (n/2 1 1) 5 7th values from the ordered list: 66.4 1 67.4 | 5 66.90 x 5 2 Note that if the largest observation 79.0 had not been included in the sample, the resulting sample median for the n 5 11 remaining observations would have been the single middle value 66.4 (the [n 1 1]/2 5 6th ordered value, i.e. the 6th value in from either end of the ordered list). The sample mean is x 5 gxi 5 816.1/12 5 68.01, a bit more than a full minute larger than the median. The mean is pulled out a bit relative to the median because the sample “stretches out” somewhat more on the upper end than on the lower end. ■ The data in Example 1.15 illustrates an important property of | x in contrast to x: The sample median is very insensitive to outliers. If, for example, we increased the two largest xis from 75.7 and 79.0 to 85.7 and 89.0, respectively, | x would be unaffected. Thus, in the treatment of outlying data values, x and | x are at opposite ends of a spectrum. Both quantities describe where the data is centered, but they will not in general be equal because they focus on different aspects of the sample. Analogous to | x as the middle value in the sample is a middle value in the pop|. As with x and m, we can think of ulation, the population median, denoted by m | |. In Example 1.15, we might using the sample median x to make an inference about m | use x 5 66.90 as an estimate of the median time for the population of all recordings. A median is often used to describe income or salary data (because it is not greatly influenced by a few large salaries). If the median salary for a sample of engix 5 $66,416, we might use this as a basis for concluding that the median neers were | salary for all engineers exceeds $60,000. | will not generally be identical. If the The population mean m and median m population distribution is positively or negatively skewed, as pictured in Figure |. When this is the case, in making inferences we must first decide 1.17, then m 2 m which of the two population characteristics is of greater interest and then proceed accordingly. ~ ␮␮ (a) Negative skew Figure 1.17 ~ ␮ ⫽␮ (b) Symmetric ~␮ ␮ (c) Positive skew Three different shapes for a population distribution Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 32 CHAPTER 1 Overview and Descriptive Statistics Other Measures of Location: Quartiles, Percentiles, and Trimmed Means The median (population or sample) divides the data set into two parts of equal size. To obtain finer measures of location, we could divide the data into more than two such parts. Roughly speaking, quartiles divide the data set into four equal parts, with the observations above the third quartile constituting the upper quarter of the data set, the second quartile being identical to the median, and the first quartile separating the lower quarter from the upper three-quarters. Similarly, a data set (sample or population) can be even more finely divided using percentiles; the 99th percentile separates the highest 1% from the bottom 99%, and so on. Unless the number of observations is a multiple of 100, care must be exercised in obtaining percentiles. We will use percentiles in Chapter 4 in connection with certain models for infinite populations and so postpone discussion until that point. The mean is quite sensitive to a single outlier, whereas the median is impervious to many outliers. Since extreme behavior of either type might be undesirable, we briefly consider alternative measures that are neither as sensitive as x nor as insensitive as | x . To motivate these alternatives, note that x and | x are at opposite extremes of the same “family” of measures. The mean is the average of all the data, whereas the median results from eliminating all but the middle one or two values and then averaging. To paraphrase, the mean involves trimming 0% from each end of the sample, whereas for the median the maximum possible amount is trimmed from each end. A trimmed mean is a compromise between x and | x . A 10% trimmed mean, for example, would be computed by eliminating the smallest 10% and the largest 10% of the sample and then averaging what remains. Example 1.16 The production of Bidri is a traditional craft of India. Bidri wares (bowls, vessels, and so on) are cast from an alloy containing primarily zinc along with some copper. Consider the following observations on copper content (%) for a sample of Bidri artifacts in London’s Victoria and Albert Museum (“Enigmas of Bidri,” Surface Engr., 2005: 333–339), listed in increasing order: 2.0 3.4 2.4 3.4 2.5 2.6 3.6 3.6 2.6 3.6 2.7 3.6 2.7 3.7 2.8 4.4 3.0 4.6 3.1 4.7 3.2 4.8 3.3 5.3 3.3 10.1 Figure 1.18 is a dotplot of the data. A prominent feature is the single outlier at the upper end; the distribution is somewhat sparser in the region of larger values than is the case for smaller values. The sample mean and median are 3.65 and 3.35, respectively. A trimmed mean with a trimming percentage of 100(2/26) 5 7.7% results from eliminating the two smallest and two largest observations; this gives xtr(7.7) 5 3.42. Trimming here eliminates the larger outlier and so pulls the trimmed mean toward the median. 1 2 3 4 5 6 7 8 9 10 11 x– x– tr (7.7) x~ Figure 1.18 Dotplot of copper contents from Example 1.16 ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.3 Measures of Location 33 A trimmed mean with a moderate trimming percentage—someplace between 5% and 25%—will yield a measure of center that is neither as sensitive to outliers as is the mean nor as insensitive as the median. If the desired trimming percentage is 100a% and na is not an integer, the trimmed mean must be calculated by interpolation. For example, consider a 5 .10 for a 10% trimming percentage and n 5 26 as in Example 1.16. Then xtr(10) would be the appropriate weighted average of the 7.7% trimmed mean calculated there and the 11.5% trimmed mean resulting from trimming three observations from each end. Categorical Data and Sample Proportions When the data is categorical, a frequency distribution or relative frequency distribution provides an effective tabular summary of the data. The natural numerical summary quantities in this situation are the individual frequencies and the relative frequencies. For example, if a survey of individuals who own digital cameras is undertaken to study brand preference, then each individual in the sample would identify the brand of camera that he or she owned, from which we could count the number owning Canon, Sony, Kodak, and so on. Consider sampling a dichotomous population—one that consists of only two categories (such as voted or did not vote in the last election, does or does not own a digital camera, etc.). If we let x denote the number in the sample falling in category 1, then the number in category 2 is n 2 x. The relative frequency or sample proportion in category 1 is x/n and the sample proportion in category 2 is 1 2 x/n. Let’s denote a response that falls in category 1 by a 1 and a response that falls in category 2 by a 0. A sample size of n 5 10 might then yield the responses 1, 1, 0, 1, 1, 1, 0, 0, 1, 1. The sample mean for this numerical sample is (since number of 1s 5 x 5 7) x1 1 c1 xn 1 1 1 1 0 1 c1 1 1 1 7 x 5 5 5 5 sample proportion n 10 10 n More generally, focus attention on a particular category and code the sample results so that a 1 is recorded for an observation in the category and a 0 for an observation not in the category. Then the sample proportion of observations in the category is the sample mean of the sequence of 1s and 0s. Thus a sample mean can be used to summarize the results of a categorical sample. These remarks also apply to situations in which categories are defined by grouping values in a numerical sample or population (e.g., we might be interested in knowing whether individuals have owned their present automobile for at least 5 years, rather than studying the exact length of ownership). Analogous to the sample proportion x/n of individuals or objects falling in a particular category, let p represent the proportion of those in the entire population falling in the category. As with x/n, p is a quantity between 0 and 1, and while x/n is a sample characteristic, p is a characteristic of the population. The relationship | and between x and m. between the two parallels the relationship between | x and m In particular, we will subsequently use x/n to make inferences about p. If, for example, a sample of 100 car owners reveals that 22 owned their car at least 5 years, then we might use 22/100 5 .22 as a point estimate of the proportion of all owners who have owned their car at least 5 years. With k categories (k . 2), we can use the k sample proportions to answer questions about the population proportions p1, c, pk. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 34 CHAPTER 1 Overview and Descriptive Statistics EXERCISES Section 1.3 (33–43) 33. The May 1, 2009 issue of The Montclarian reported the following home sale amounts for a sample of homes in Alameda, CA that were sold the previous month (1000s of $): reexpress each observation in ksi, or can the values calculated in part (a) be used directly? [Hint: 1 kg 5 2.2 lb.] 590 815 575 608 350 1285 408 540 555 679 36. A sample of 26 offshore oil workers took part in a simulated escape exercise, resulting in the accompanying data on time (sec) to complete the escape (“Oxygen Consumption and Ventilation During Escape from an Offshore Platform,” Ergonomics, 1997: 281–292): a. Calculate and interpret the sample mean and median. b. Suppose the 6th observation had been 985 rather than 1285. How would the mean and median change? c. Calculate a 20% trimmed mean by first trimming the two smallest and two largest observations. d. Calculate a 15% trimmed mean. 34. Exposure to microbial products, especially endotoxin, may have an impact on vulnerability to allergic diseases. The article “Dust Sampling Methods for Endotoxin—An Essential, But Underestimated Issue” (Indoor Air, 2006: 20–27) considered various issues associated with determining endotoxin concentration. The following data on concentration (EU/mg) in settled dust for one sample of urban homes and another of farm homes was kindly supplied by the authors of the cited article. U: 6.0 5.0 11.0 33.0 4.0 5.0 80.0 18.0 35.0 17.0 23.0 F: 4.0 14.0 11.0 9.0 9.0 8.0 4.0 20.0 5.0 8.9 21.0 9.2 3.0 2.0 0.3 a. Determine the sample mean for each sample. How do they compare? b. Determine the sample median for each sample. How do they compare? Why is the median for the urban sample so different from the mean for that sample? c. Calculate the trimmed mean for each sample by deleting the smallest and largest observation. What are the corresponding trimming percentages? How do the values of these trimmed means compare to the corresponding means and medians? 35. The minimum injection pressure (psi) for injection molding specimens of high amylose corn was determined for eight different specimens (higher pressure corresponds to greater processing difficulty), resulting in the following observations (from “Thermoplastic Starch Blends with a Polyethylene-Co-Vinyl Alcohol: Processability and Physical Properties,” Polymer Engr. and Science, 1994: 17–23): 15.0 13.0 18.0 14.5 12.0 11.0 8.9 8.0 a. Determine the values of the sample mean, sample median, and 12.5% trimmed mean, and compare these values. b. By how much could the smallest sample observation, currently 8.0, be increased without affecting the value of the sample median? c. Suppose we want the values of the sample mean and median when the observations are expressed in kilograms per square inch (ksi) rather than psi. Is it necessary to 389 373 392 356 373 369 359 370 374 363 364 359 375 366 356 424 364 403 325 325 334 394 339 397 402 393 a. Construct a stem-and-leaf display of the data. How does it suggest that the sample mean and median will compare? b. Calculate the values of the sample mean and median. [Hint: gxi 5 9638.] c. By how much could the largest time, currently 424, be increased without affecting the value of the sample median? By how much could this value be decreased without affecting the value of the sample median? d. What are the values of x and | x when the observations are reexpressed in minutes? 37. The article “Snow Cover and Temperature Relationships in North America and Eurasia” (J. Climate and Applied Meteorology, 1983: 460–469) used statistical techniques to relate the amount of snow cover on each continent to average continental temperature. Data presented there included the following ten observations on October snow cover for Eurasia during the years 1970–1979 (in million km2): 6.5 12.0 14.9 10.0 10.7 7.9 21.9 12.5 14.5 9.2 What would you report as a representative, or typical, value of October snow cover for this period, and what prompted your choice? 38. Blood pressure values are often reported to the nearest 5 mmHg (100, 105, 110, etc.). Suppose the actual blood pressure values for nine randomly selected individuals are 118.6 127.4 138.4 130.0 113.7 122.0 108.3 131.5 133.2 a. What is the median of the reported blood pressure values? b. Suppose the blood pressure of the second individual is 127.6 rather than 127.4 (a small change in a single value). How does this affect the median of the reported values? What does this say about the sensitivity of the median to rounding or grouping in the data? 39. The propagation of fatigue cracks in various aircraft parts has been the subject of extensive study in recent years. The accompanying data consists of propagation lives (flight hours/104) to reach a given crack size in fastener holes intended for use in military aircraft (“Statistical Crack Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 35 1.4 Measures of Variability Propagation in Fastener Holes Under Spectrum Loading,” J. Aircraft, 1983: 1028–1032): .736 1.011 .863 1.064 .865 1.109 .913 1.132 .915 1.140 .937 1.153 .983 1.253 1.007 1.394 a. Compute and compare the values of the sample mean and median. b. By how much could the largest sample observation be decreased without affecting the value of the median? 40. Compute the sample median, 25% trimmed mean, 10% trimmed mean, and sample mean for the lifetime data given in Exercise 27, and compare these measures. 41. A sample of n 5 10 automobiles was selected, and each was subjected to a 5-mph crash test. Denoting a car with no visible damage by S (for success) and a car with such damage by F, results were as follows: c. Suppose it is decided to include 15 more cars in the experiment. How many of these would have to be S’s to give x/n 5 .80 for the entire sample of 25 cars? 42. a. If a constant c is added to each xi in a sample, yielding yi 5 xi 1 c, how do the sample mean and median of the yis relate to the mean and median of the xis? Verify your conjectures. b. If each xi is multiplied by a constant c, yielding yi 5 cxi, answer the question of part (a). Again, verify your conjectures. 43. An experiment to study the lifetime (in hours) for a certain type of component involved putting ten components into operation and observing them for 100 hours. Eight of the components failed during that period, and those lifetimes were recorded. Denote the lifetimes of the two components still functioning after 100 hours by 1001 . The resulting sample observations were S S F S S S F F S S 48 a. What is the value of the sample proportion of successes x/n? b. Replace each S with a 1 and each F with a 0. Then calculate x for this numerically coded sample. How does x compare to x/n? 79 1001 35 92 86 57 1001 17 29 Which of the measures of center discussed in this section can be calculated, and what are the values of those measures? [Note: The data from this experiment is said to be “censored on the right.”] 1.4 Measures of Variability Reporting a measure of center gives only partial information about a data set or distribution. Different samples or populations may have identical measures of center yet differ from one another in other important ways. Figure 1.19 shows dotplots of three samples with the same mean and median, yet the extent of spread about the center is different for all three samples. The first sample has the largest amount of variability, the third has the smallest amount, and the second is intermediate to the other two in this respect. 1: * * * * * * * * * 2: 3: 30 Figure 1.19 40 50 60 70 Samples with identical measures of center but different amounts of variability Measures of Variability for Sample Data The simplest measure of variability in a sample is the range, which is the difference between the largest and smallest sample values. The value of the range for sample 1 in Figure 1.19 is much larger than it is for sample 3, reflecting more variability in the first sample than in the third. A defect of the range, though, is that it depends on only the two most extreme observations and disregards the positions of the remaining Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 36 CHAPTER 1 Overview and Descriptive Statistics n 2 2 values. Samples 1 and 2 in Figure 1.19 have identical ranges, yet when we take into account the observations between the two extremes, there is much less variability or dispersion in the second sample than in the first. Our primary measures of variability involve the deviations from the mean, x1 2 x, x2 2 x, c, xn 2 x. That is, the deviations from the mean are obtained by subtracting x from each of the n sample observations. A deviation will be positive if the observation is larger than the mean (to the right of the mean on the measurement axis) and negative if the observation is smaller than the mean. If all the deviations are small in magnitude, then all xis are close to the mean and there is little variability. Alternatively, if some of the deviations are large in magnitude, then some xis lie far from x, suggesting a greater amount of variability. A simple way to combine the deviations into a single quantity is to average them. Unfortunately, this is a bad idea: n sum of deviations 5 g (xi 2 x) 5 0 i51 so that the average deviation is always zero. The verification uses several standard rules of summation and the fact that gx 5 x 1 x 1 c 1 x 5 nx: g (xi 2 x) 5 g xi 2 g x 5 g xi 2 nx 5 g xi 2 na n g xi b 5 0 1 How can we prevent negative and positive deviations from counteracting one another when they are combined? One possibility is to work with the absolute values of the deviations and calculate the average absolute deviation g u xi 2 x u/n. Because the absolute value operation leads to a number of theoretical difficulties, consider instead the squared deviations (x1 2 x)2, (x2 2 x)2, c, (xn 2 x)2. Rather than use the average squared deviation g(xi 2 x)2/n, for several reasons we divide the sum of squared deviations by n 2 1 rather than n. DEFINITION The sample variance, denoted by s2, is given by s2 5 Sxx g(xi 2 x)2 5 n21 n21 The sample standard deviation, denoted by s, is the (positive) square root of the variance: s 5 2s 2 Note that s2 and s are both nonnegative. The unit for s is the same as the unit for each of the xis. If, for example, the observations are fuel efficiencies in miles per gallon, then we might have s 5 2.0 mpg. A rough interpretation of the sample standard deviation is that it is the size of a typical or representative deviation from the sample mean within the given sample. Thus if s 5 2.0 mpg, then some xi’s in the sample are closer than 2.0 to x, whereas others are farther away; 2.0 is a representative (or “standard”) deviation from the mean fuel efficiency. If s 5 3.0 for a second sample of cars of another type, a typical deviation in this sample is roughly 1.5 times what it is in the first sample, an indication of more variability in the second sample. Example 1.17 The Web site www.fueleconomy.gov contains a wealth of information about fuel characteristics of various vehicles. In addition to EPA mileage ratings, there are Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.4 Measures of Variability 37 many vehicles for which users have reported their own values of fuel efficiency (mpg). Consider the following sample of n 5 11 efficiencies for the 2009 Ford Focus equipped with an automatic transmission (for this model, EPA reports an overall rating of 27 mpg–24 mpg for city driving and 33 mpg for highway driving): Car xi xi 2 x sxi 2 xd2 1 2 3 4 5 6 7 8 9 10 11 27.3 27.9 32.9 35.2 44.9 39.9 30.0 29.7 28.5 32.0 37.6 25.96 25.36 20.36 1.94 11.64 6.64 23.26 23.56 24.76 21.26 4.34 35.522 28.730 0.130 3.764 135.490 44.090 10.628 12.674 22.658 1.588 18.836 gxi 5 365.9 g sxi 2 xd 5 .04 g sxi 2 xd2 5 314.106 x 5 33.26 Effects of rounding account for the sum of deviations not being exactly zero. The numerator of s2 is Sxx 5 314.106, from which s2 5 Sxx 314.106 5 5 31.41, n21 11 2 1 s 5 5.60 The size of a representative deviation from the sample mean 33.26 is roughly 5.6 mpg. Note: Of the nine people who also reported driving behavior, only three did more than 80% of their driving in highway mode; we bet you can guess which cars they drove. We haven’t a clue why all 11 reported values exceed the EPA figure—maybe only drivers with really good fuel efficiencies communicate their results. ■ Motivation for s2 To explain the rationale for the divisor n 2 1 in s2, note first that whereas s2 measures sample variability, there is a measure of variability in the population called the population variance. We will use s2 (the square of the lowercase Greek letter sigma) to denote the population variance and s to denote the population standard deviation (the square root of s2). When the population is finite and consists of N values, N s2 5 g (xi 2 m)2/N i51 which is the average of all squared deviations from the population mean (for the population, the divisor is N and not N 2 1). More general definitions of s2 appear in Chapters 3 and 4. Just as x will be used to make inferences about the population mean m, we should define the sample variance so that it can be used to make inferences about s2. Now note that s2 involves squared deviations about the population mean m. If we actually knew the value of m, then we could define the sample variance as the average squared deviation of the sample xis about m. However, the value of m is almost never known, so the sum of squared deviations about x must be used. But the xis tend to be closer to their average x than to the population average m, so to compensate for this Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 38 CHAPTER 1 Overview and Descriptive Statistics the divisor n 2 1 is used rather than n. In other words, if we used a divisor n in the sample variance, then the resulting quantity would tend to underestimate s2 (produce estimated values that are too small on the average), whereas dividing by the slightly smaller n 2 1 corrects this underestimating. It is customary to refer to s2 as being based on n 2 1 degrees of freedom (df). This terminology reflects the fact that although s2 is based on the n quantities x1 2 x, x2 2 x, c, xn 2 x, these sum to 0, so specifying the values of any n 2 1 of the quantities determines the remaining value. For example, if n 5 4 and x1 2 x 5 8, x2 2 x 5 26, and x4 2 x 5 24, then automatically x3 2 x 5 2, so only three of the four values of xi 2 x are freely determined (3 df). A Computing Formula for s2 It is best to obtain s2 from statistical software or else use a calculator that allows you to enter data into memory and then view s2 with a single keystroke. If your calculator does not have this capability, there is an alternative formula for Sxx that avoids calculating the deviations. The formula involves both Agxi B 2, summing and then squaring, and g x 2i , squaring and then summing. An alternative expression for the numerator of s2 is Agxi B 2 Sxx 5 g(xi 2 x)2 5 gx 2i 2 n Proof Because x 5 gxi /n, nx 2 5 Agxi B 2/n. Then, g(x i 2 x )2 5 g(x 2i 2 2x # x i 1 x 2) 5 gx 2i 2 2x gx i 1 g(x)2 5 gx 2i 2 2x # nx 1 n(x)2 5 gx 2i 2 n(x)2 Example 1.18 Traumatic knee dislocation often requires surgery to repair ruptured ligaments. One measure of recovery is range of motion (measured as the angle formed when, starting with the leg straight, the knee is bent as far as possible). The given data on postsurgical range of motion appeared in the article “Reconstruction of the Anterior and Posterior Cruciate Ligaments After Knee Dislocation” (Amer. J. Sports Med., 1999: 189–197): 154 142 137 133 122 126 135 135 108 120 127 134 122 The sum of these 13 sample observations is gxi 5 1695, and the sum of their squares is g x 2i 5 (154)2 1 (142)2 1 c 1 (122)2 5 222,581 Thus the numerator of the sample variance is Sxx 5 gx 2i 2 [(gxi)2]/n 5 222,581 2 (1695)2/13 5 1579.0769 from which s 2 5 1579.0769/12 5 131.59 and s 5 11.47. ■ Both the defining formula and the computational formula for s2 can be sensitive to rounding, so as much decimal accuracy as possible should be used in intermediate calculations. Several other properties of s2 can enhance understanding and facilitate computation. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.4 Measures of Variability PROPOSITION 39 Let x1, x2, c, xn be a sample and c be any nonzero constant. 1. If y1 5 x1 1 c, y2 5 x2 1 c, c , yn 5 xn 1 c, then s 2y 5 s 2x, and 2. If y1 5 cx1, c, yn 5 cxn, then s 2y 5 c2s 2x , sy 5 u c usx where s 2x is the sample variance of the x’s and s 2y is the sample variance of the y’s. In words, Result 1 says that if a constant c is added to (or subtracted from) each data value, the variance is unchanged. This is intuitive, since adding or subtracting c shifts the location of the data set but leaves distances between data values unchanged. According to Result 2, multiplication of each xi by c results in s2 being multiplied by a factor of c2. These properties can be proved by noting in Result 1 that y 5 x 1 c and in Result 2 that y 5 cx. Boxplots Stem-and-leaf displays and histograms convey rather general impressions about a data set, whereas a single summary such as the mean or standard deviation focuses on just one aspect of the data. In recent years, a pictorial summary called a boxplot has been used successfully to describe several of a data set’s most prominent features. These features include (1) center, (2) spread, (3) the extent and nature of any departure from symmetry, and (4) identification of “outliers,” observations that lie unusually far from the main body of the data. Because even a single outlier can drastically affect the values of x and s, a boxplot is based on measures that are “resistant” to the presence of a few outliers—the median and a measure of variability called the fourth spread. DEFINITION Order the n observations from smallest to largest and separate the smallest half from the largest half; the median | x is included in both halves if n is odd. Then the lower fourth is the median of the smallest half and the upper fourth is the median of the largest half. A measure of spread that is resistant to outliers is the fourth spread fs, given by fs 5 upper fourth 2 lower fourth Roughly speaking, the fourth spread is unaffected by the positions of those observations in the smallest 25% or the largest 25% of the data. Hence it is resistant to outliers. The simplest boxplot is based on the following five-number summary: smallest xi lower fourth median upper fourth largest xi First, draw a horizontal measurement scale. Then place a rectangle above this axis; the left edge of the rectangle is at the lower fourth, and the right edge is at the upper fourth (so box width 5 fs). Place a vertical line segment or some other symbol inside the rectangle at the location of the median; the position of the median symbol relative to the two edges conveys information about skewness in the middle 50% of the data. Finally, draw “whiskers” out from either end of the rectangle to the smallest and largest observations. A boxplot with a vertical orientation can also be drawn by making obvious modifications in the construction process. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 40 CHAPTER 1 Overview and Descriptive Statistics Example 1.19 Ultrasound was used to gather the accompanying corrosion data on the thickness of the floor plate of an aboveground tank used to store crude oil (“Statistical Analysis of UT Corrosion Data from Floor Plates of a Crude Oil Aboveground Storage Tank,” Materials Eval., 1994: 846–849); each observation is the largest pit depth in the plate, expressed in milli-in. ⎧ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎨ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎩ ⎧ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎨ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎩ 40 52 55 60 70 75 85 85 90 90 92 94 94 95 98 100 115 125 125 The five-number summary is as follows: smallest xi 5 40 lower fourth 5 72.5 | x 5 90 largest xi 5 125 upper fourth 5 96.5 Figure 1.20 shows the resulting boxplot. The right edge of the box is much closer to the median than is the left edge, indicating a very substantial skew in the middle half of the data. The box width (fs) is also reasonably large relative to the range of the data (distance between the tips of the whiskers). Depth 40 50 60 70 Figure 1.20 80 90 100 110 120 130 A boxplot of the corrosion data Figure 1.21 shows Minitab output from a request to describe the corrosion data. Q1 and Q3 are the lower and upper quartiles; these are similar to the fourths but are calculated in a slightly different manner. SE Mean is s/ 1n; this will be an important quantity in our subsequent work concerning inferences about m. Variable depth N 19 Mean 86.32 Median 90.00 TrMean 86.76 Variable depth Minimum 40.00 Maximum 125.00 Q1 70.00 Q3 98.00 Figure 1.21 StDev 23.32 SE Mean 5.35 Minitab description of the pit-depth data ■ Boxplots That Show Outliers A boxplot can be embellished to indicate explicitly the presence of outliers. Many inferential procedures are based on the assumption that the population distribution is normal (a certain type of bell curve). Even a single extreme outlier in the sample warns the investigator that such procedures may be unreliable, and the presence of several mild outliers conveys the same message. DEFINITION Any observation farther than 1.5fs from the closest fourth is an outlier. An outlier is extreme if it is more than 3fs from the nearest fourth, and it is mild otherwise. Let’s now modify our previous construction of a boxplot by drawing a whisker out from each end of the box to the smallest and largest observations that are not outliers. Each mild outlier is represented by a closed circle and each extreme outlier by an open circle. Some statistical computer packages do not distinguish between mild and extreme outliers. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 41 1.4 Measures of Variability Example 1.20 The Clean Water Act and subsequent amendments require that all waters in the United States meet specific pollution reduction goals to ensure that water is “fishable and swimmable.” The article “Spurious Correlation in the USEPA Rating Curve Method for Estimating Pollutant Loads” (J. of Environ. Engr., 2008: 610–618) investigated various techniques for estimating pollutant loads in watersheds; the authors “discuss the imperative need to use sound statistical methods” for this purpose. Among the data considered is the following sample of TN (total nitrogen) loads (kg N/day) from a particular Chesapeake Bay location, displayed here in increasing order. 9.69 30.75 49.98 66.14 103.61 143.75 312.45 1529.35 13.16 31.54 50.06 67.68 106.28 149.64 352.09 17.09 35.07 55.02 81.40 106.80 167.79 371.47 18.12 36.99 57.00 90.80 108.69 182.50 444.68 Relevant summary quantities are | x 5 92.17 lower 4th 5 45.64 fs 5 122.15 1.5fs 5 183.225 23.70 40.32 58.41 92.17 114.61 192.55 460.86 24.07 42.51 61.31 92.42 120.86 193.53 563.92 24.29 45.64 64.25 100.82 124.54 271.57 690.11 26.43 48.22 65.24 101.94 143.27 292.61 826.54 upper 4th 5 167.79 3fs 5 366.45 th Subtracting 1.5fs from the lower 4 gives a negative number, and none of the observations are negative, so there are no outliers on the lower end of the data. However, upper 4th 1 1.5fs 5 351.015 upper 4th 1 3fs 5 534.24 Thus the four largest observations—563.92, 690.11, 826.54, and 1529.35—are extreme outliers, and 352.09, 371.47, 444.68, and 460.86 are mild outliers. The whiskers in the boxplot in Figure 1.22 extend out to the smallest observation, 9.69, on the low end and 312.45, the largest observation that is not an outlier, on the upper end. There is some positive skewness in the middle half of the data (the median line is somewhat closer to the left edge of the box than to the right edge) and a great deal of positive skewness overall. load 0 200 Figure 1.22 400 600 800 1000 Daily nitrogen load 1200 1400 1600 A boxplot of the nitrogen load data showing mild and extreme outliers ■ Comparative Boxplots A comparative or side-by-side boxplot is a very effective way of revealing similarities and differences between two or more data sets consisting of observations on the same variable—fuel efficiency observations for four different types of automobiles, crop yields for three different varieties, and so on. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 42 CHAPTER 1 Overview and Descriptive Statistics Example 1.21 In recent years, some evidence suggests that high indoor radon concentration may be linked to the development of childhood cancers, but many health professionals remain unconvinced. A recent article (“Indoor Radon and Childhood Cancer,” The Lancet, 1991: 1537–1538) presented the accompanying data on radon concentration (Bq/m3) in two different samples of houses. The first sample consisted of houses in which a child diagnosed with cancer had been residing. Houses in the second sample had no recorded cases of childhood cancer. Figure 1.23 presents a stem-and-leaf display of the data. 1. Cancer 2. No cancer 9683795 86071815066815233150 12302731 8349 5 7 0 1 2 3 4 5 6 7 8 HI: 210 Figure 1.23 95768397678993 12271713114 99494191 839 55 5 Stem: Tens digit Leaf: Ones digit Stem-and-leaf display for Example 1.21 Numerical summary quantities are as follows: Cancer No cancer x | x s fs 22.8 19.2 16.0 12.0 31.7 17.0 11.0 18.0 The values of both the mean and median suggest that the cancer sample is centered somewhat to the right of the no-cancer sample on the measurement scale. The mean, however, exaggerates the magnitude of this shift, largely because of the observation 210 in the cancer sample. The values of s suggest more variability in the cancer sample than in the no-cancer sample, but this impression is contradicted by the fourth spreads. Again, the observation 210, an extreme outlier, is the culprit. Figure 1.24 shows a comparative boxplot from the S-Plus computer package. The no-cancer box Radon concentration 200 150 100 50 0 No cancer Figure 1.24 Cancer A boxplot of the data in Example 1.21, from S-Plus Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 1.4 Measures of Variability 43 is stretched out compared with the cancer box (fs 5 18 vs. fs 5 11), and the positions of the median lines in the two boxes show much more skewness in the middle half of the no-cancer sample than the cancer sample. Outliers are represented by horizontal line segments, and there is no distinction between mild and extreme outliers. ■ EXERCISES Section 1.4 (44–61) 44. The article “Oxygen Consumption During Fire Suppression: Error of Heart Rate Estimation” (Ergonomics, 1991: 1469–1474) reported the following data on oxygen consumption (mL/kg/min) for a sample of ten firefighters performing a fire-suppression simulation: 29.5 49.3 30.6 28.2 28.0 26.3 33.9 29.4 23.5 31.6 Compute the following: a. The sample range b. The sample variance s2 from the definition (i.e., by first computing deviations, then squaring them, etc.) c. The sample standard deviation d. s2 using the shortcut method 45. The value of Young’s modulus (GPa) was determined for cast plates consisting of certain intermetallic substrates, resulting in the following sample observations (“Strength and Modulus of a Molybdenum-Coated Ti-25Al-10Nb-3U1Mo Intermetallic,” J. of Materials Engr. and Performance, 1997: 46–50): 116.4 115.9 114.6 115.2 115.8 a. Calculate x and the deviations from the mean. b. Use the deviations calculated in part (a) to obtain the sample variance and the sample standard deviation. c. Calculate s2 by using the computational formula for the numerator Sxx. d. Subtract 100 from each observation to obtain a sample of transformed values. Now calculate the sample variance of these transformed values, and compare it to s2 for the original data. 46. The accompanying observations on stabilized viscosity (cP) for specimens of a certain grade of asphalt with 18% rubber added are from the article “Viscosity Characteristics of Rubber-Modified Asphalts” (J. of Materials in Civil Engr., 1996: 153–156): 2781 2900 3013 2856 2888 a. What are the values of the sample mean and sample median? b. Calculate the sample variance using the computational formula. [Hint: First subtract a convenient number from each observation.] 47. Calculate and interpret the values of the sample median, sample mean, and sample standard deviation for the following observations on fracture strength (MPa, read from a graph in “Heat-Resistant Active Brazing of Silicon Nitride: Mechanical Evaluation of Braze Joints,” Welding J., August, 1997): 87 93 96 98 105 114 128 131 142 168 48. Exercise 34 presented the following data on endotoxin concentration in settled dust both for a sample of urban homes and for a sample of farm homes: U: F: 6.0 5.0 11.0 33.0 4.0 5.0 80.0 18.0 35.0 17.0 23.0 4.0 14.0 11.0 9.0 9.0 8.0 4.0 20.0 5.0 8.9 21.0 9.2 3.0 2.0 0.3 a. Determine the value of the sample standard deviation for each sample, interpret these values, and then contrast variability in the two samples. [Hint: gxi 5 237.0 for the urban sample and 5 128.4 for the farm sample, and gx 2i 5 10,079 for the urban sample and 1617.94 for the farm sample.] b. Compute the fourth spread for each sample and compare. Do the fourth spreads convey the same message about variability that the standard deviations do? Explain. c. The authors of the cited article also provided endotoxin concentrations in dust bag dust: U: 34.0 49.0 13.0 33.0 24.0 24.0 35.0 104.0 34.0 40.0 38.0 1.0 F: 2.0 64.0 6.0 17.0 35.0 11.0 17.0 13.0 5.0 27.0 23.0 28.0 10.0 13.0 0.2 Construct a comparative boxplot (as did the cited paper) and compare and contrast the four samples. 49. A study of the relationship between age and various visual functions (such as acuity and depth perception) reported the following observations on the area of scleral lamina (mm2) from human optic nerve heads (“Morphometry of Nerve Fiber Bundle Pores in the Optic Nerve Head of the Human,” Experimental Eye Research, 1988: 559–568): 2.75 4.33 2.62 3.46 2.74 4.52 3.85 2.43 2.34 3.65 2.74 2.78 3.93 3.56 4.21 3.01 3.88 a. Calculate gxi and gx 2i . b. Use the values calculated in part (a) to compute the sample variance s2 and then the sample standard deviation s. 50. In 1997 a woman sued a computer keyboard manufacturer, charging that her repetitive stress injuries were caused by the keyboard (Genessy v. Digital Equipment Corp.). The injury awarded about $3.5 million for pain and suffering, but the court then set aside that award as being unreasonable Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 44 CHAPTER 1 Overview and Descriptive Statistics compensation. In making this determination, the court identified a “normative” group of 27 similar cases and specified a reasonable award as one within two standard deviations of the mean of the awards in the 27 cases. The 27 awards were (in $1000s) 37, 60, 75, 115, 135, 140, 149, 150, 238, 290, 340, 410, 600, 750, 750, 750, 1050, 1100, 1139, 1150, 1200, 1200, 1250, 1576, 1700, 1825, and 2000, from which gxi 5 20,179, g x 2i 5 24,657,511. What is the maximum possible amount that could be awarded under the twostandard-deviation rule? 51. The article “A Thin-Film Oxygen Uptake Test for the Evaluation of Automotive Crankcase Lubricants” (Lubric. Engr., 1984: 75–83) reported the following data on oxidation-induction time (min) for various commercial oils: 87 103 130 160 180 195 132 145 211 105 145 153 152 138 87 99 93 119 129 a. Calculate the sample variance and standard deviation. b. If the observations were reexpressed in hours, what would be the resulting values of the sample variance and sample standard deviation? Answer without actually performing the reexpression. 52. The first four deviations from the mean in a sample of n 5 5 reaction times were .3, .9, 1.0, and 1.3. What is the fifth deviation from the mean? Give a sample for which these are the five deviations from the mean. 53. A mutual fund is a professionally managed investment scheme that pools money from many investors and invests in a variety of securities. Growth funds focus primarily on increasing the value of investments, whereas blended funds seek a balance between current income and growth. Here is data on the expense ratio (expenses as a % of assets, from www.morningstar.com) for samples of 20 large-cap balanced funds and 20 large-cap growth funds (“large-cap” refers to the sizes of companies in which the funds invest; the population sizes are 825 and 762, respectively): Bl 1.03 1.27 0.94 0.79 1.23 1.25 2.86 1.61 1.10 0.78 1.05 1.26 1.64 1.05 0.75 0.93 1.30 0.64 0.09 0.84 Gr 0.52 0.99 0.91 1.02 1.06 1.10 0.79 1.10 1.26 1.07 1.39 1.78 2.17 1.81 0.62 1.01 1.55 2.05 1.52 1.15 x , and s for the a. Calculate and compare the values of x, | two types of funds. b. Construct a comparative boxplot for the two types of funds, and comment on interesting features. 54. Grip is applied to produce normal surface forces that compress the object being gripped. Examples include two people shaking hands, or a nurse squeezing a patient’s forearm to stop bleeding. The article “Investigation of Grip Force, Normal Force, Contact Area, Hand Size, and Handle Size for Cylindrical Handles” (Human Factors, 2008: 734–744) included the following data on grip strength (N) for a sample of 42 individuals: 16 18 18 26 33 41 54 56 66 68 87 91 95 98 106 109 111 118 127 127 135 145 147 149 151 168 172 183 189 190 200 210 220 229 230 233 238 244 259 294 329 403 a. Construct a stem-and-leaf display based on repeating each stem value twice, and comment on interesting features. b. Determine the values of the fourths and the fourthspread. c. Construct a boxplot based on the five-number summary, and comment on its features. d. How large or small does an observation have to be to qualify as an outlier? An extreme outlier? Are there any outliers? e. By how much could the observation 403, currently the largest, be decreased without affecting fs? 55. Here is a stem-and-leaf display of the escape time data introduced in Exercise 36 of this chapter. 32 33 34 35 36 37 38 39 40 41 42 a. b. c. d. 55 49 6699 34469 03345 9 2347 23 4 Determine the value of the fourth spread. Are there any outliers in the sample? Any extreme outliers? Construct a boxplot and comment on its features. By how much could the largest observation, currently 424, be decreased without affecting the value of the fourth spread? 56. The following data on distilled alcohol content (%) for a sample of 35 port wines was extracted from the article “A Method for the Estimation of Alcohol in Fortified Wines Using Hydrometer Baumé and Refractometer Brix” (Amer. J. Enol. Vitic., 2006: 486–490). Each value is an average of two duplicate measurements. 16.35 19.08 17.48 19.20 18.85 19.62 17.15 18.00 16.20 19.20 19.07 19.60 17.75 20.05 19.90 19.33 19.58 17.85 18.68 21.22 17.73 19.17 18.82 19.50 22.75 19.48 19.03 15.30 23.78 23.25 20.00 19.97 19.45 19.37 22.25 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 45 1.4 Measures of Variability a. Determine the medians, fourths, and fourth spreads for the two samples. b. Are there any outliers in either sample? Any extreme outliers? c. Construct a comparative boxplot, and use it as a basis for comparing and contrasting the ED and non-ED samples. Use methods from this chapter, including a boxplot that shows outliers, to describe and summarize the data. 57. A sample of 20 glass bottles of a particular type was selected, and the internal pressure strength of each bottle was determined. Consider the following partial sample information: median 5 202.2 upper fourth 5 216.8 lower fourth 5 196.0 Three smallest observations Three largest observations 125.8 221.3 188.1 230.5 193.7 250.2 a. Are there any outliers in the sample? Any extreme outliers? b. Construct a boxplot that shows outliers, and comment on any interesting features. 60. Observations on burst strength (lb/in2) were obtained both for test nozzle closure welds and for production cannister nozzle welds (“Proper Procedures Are the Key to Welding Radioactive Waste Cannisters,” Welding J., Aug. 1997: 61–67). 58. A company utilizes two different machines to manufacture parts of a certain type. During a single shift, a sample of n 5 20 parts produced by each machine is obtained, and the value of a particular critical dimension for each part is determined. The comparative boxplot at the bottom of this page is constructed from the resulting data. Compare and contrast the two samples. 59. Blood cocaine concentration (mg/L) was determined both for a sample of individuals who had died from cocaineinduced excited delirium (ED) and for a sample of those who had died from a cocaine overdose without excited delirium; survival time for people in both groups was at most 6 hours. The accompanying data was read from a comparative boxplot in the article “Fatal Excited Delirium Following Cocaine Use” (J. of Forensic Sciences, 1997: 25–31). Test 7200 7300 6100 7300 7300 8000 7300 6700 8000 8300 7400 Cannister 5250 5800 5625 6000 5900 5875 5900 6100 5700 5850 6050 6600 Construct a comparative boxplot and comment on interesting features (the cited article did not include such a picture, but the authors commented that they had looked at one). 61. The accompanying comparative boxplot of gasoline vapor coefficients for vehicles in Detroit appeared in the article “Receptor Modeling Approach to VOC Emission Inventory Validation” (J. of Envir. Engr., 1995: 483–490). Discuss any interesting features. Comparative boxplot for Exercise 61 Gas vapor coefficient ED 0 0 0 0 .1 .1 .1 .1 .2 .2 .3 .3 .3 .4 .5 .7 .8 1.0 1.5 2.7 2.8 3.5 4.0 8.9 9.2 11.7 21.0 Non-ED 0 0 0 0 0 .1 .1 .1 .1 .2 .2 .2 .3 .3 .3 .4 .5 .5 .6 .8 .9 1.0 1.2 1.4 1.5 1.7 2.0 3.2 3.5 4.1 4.3 4.8 5.0 5.6 5.9 6.0 6.4 7.9 8.3 8.7 9.1 9.6 9.9 11.0 11.5 12.2 12.7 14.0 16.6 17.8 70 60 50 40 Comparative boxplot for Exercise 58 30 Machine 20 2 10 Time 0 1 6 a.m. 8 a.m. 12 noon 2 p.m. 10 p.m. Dimension 85 95 105 115 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 46 CHAPTER 1 Overview and Descriptive Statistics SUPPLEMENTARY EXERCISES (62–83) 62. Consider the following information on ultimate tensile strength (lb/in) for a sample of n 5 4 hard zirconium copper wire specimens (from “Characterization Methods for Fine Copper Wire,” Wire J. Intl., Aug., 1997: 74–80): x 5 76,831 s 5 180 smallest xi 5 76,683 largest xi 5 77,048 Determine the values of the two middle sample observations (and don’t do it by successive guessing!). 63. A sample of 77 individuals working at a particular office was selected and the noise level (dBA) experienced by each individual was determined, yielding the following data (“Acceptable Noise Levels for Construction Site Offices,” Building Serv. Engr. Research and Technology, 2009: 87–94). 55.3 56.1 57.9 63.8 65.3 68.7 74.6 55.3 56.1 57.9 63.8 65.3 69.0 74.6 55.3 56.8 58.8 63.9 65.3 70.4 74.6 55.9 56.8 58.8 63.9 65.3 70.4 74.6 55.9 57.0 58.8 63.9 67.4 71.2 79.3 55.9 57.0 59.8 64.7 67.4 71.2 79.3 55.9 57.0 59.8 64.7 67.4 71.2 79.3 56.1 57.8 59.8 64.7 67.4 73.0 79.3 56.1 57.8 62.2 65.1 68.7 73.0 83.0 56.1 57.8 62.2 65.1 68.7 73.1 83.0 56.1 57.9 63.8 65.1 68.7 73.1 83.0 Use various techniques discussed in this chapter to organize, summarize, and describe the data. 64. Fretting is a wear process that results from tangential oscillatory movements of small amplitude in machine parts. The article “Grease Effect on Fretting Wear of Mild Steel” (Industrial Lubrication and Tribology, 2008: 67–78) included the following data on volume wear (1024mm3) for base oils having four different viscosities. Viscosity 20.4 30.2 89.4 252.6 Wear 58.8 44.5 73.3 30.6 30.8 47.1 57.1 24.2 27.3 48.7 66.0 16.6 29.9 41.6 93.8 38.9 17.7 32.8 133.2 28.7 76.5 18.3 81.1 23.6 a. The sample coefficient of variation 100s/ x assesses the extent of variability relative to the mean (specifically, the standard deviation as a percentage of the mean). Calculate the coefficient of variation for the sample at each viscosity. Then compare the results and comment. b. Construct a comparative boxplot of the data and comment on interesting features. 65. The accompanying frequency distribution of fracture strength (MPa) observations for ceramic bars fired in a particular kiln appeared in the article “Evaluating Tunnel Kiln Performance” (Amer. Ceramic Soc. Bull., Aug. 1997: 59–63). 812,83 832,85 852,87 872,89 892,91 Class Frequency 6 7 17 30 43 912,93 932,95 952,97 972,99 Class Frequency 28 22 13 3 a. Construct a histogram based on relative frequencies, and comment on any interesting features. b. What proportion of the strength observations are at least 85? Less than 95? c. Roughly what proportion of the observations are less than 90? 66. A deficiency of the trace element selenium in the diet can negatively impact growth, immunity, muscle and neuromuscular function, and fertility. The introduction of selenium supplements to dairy cows is justified when pastures have low selenium levels. Authors of the paper “Effects of ShortTerm Supplementation with Selenised Yeast on Milk Production and Composition of Lactating Cows” (Australian J. of Dairy Tech., 2004: 199–203) supplied the following data on milk selenium concentration (mg/L) for a sample of cows given a selenium supplement and a control sample given no supplement, both initially and after a 9-day period. Obs 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 Init Se 11.4 9.6 10.1 8.5 10.3 10.6 11.8 9.8 10.9 10.3 10.2 11.4 9.2 10.6 10.8 8.2 Init Cont 9.1 8.7 9.7 10.8 10.9 10.6 10.1 12.3 8.8 10.4 10.9 10.4 11.6 10.9 Final Se 138.3 104.0 96.4 89.0 88.0 103.8 147.3 97.1 172.6 146.3 99.0 122.3 103.0 117.8 121.5 93.0 Final Cont 9.3 8.8 8.8 10.1 9.6 8.6 10.4 12.4 9.3 9.5 8.4 8.7 12.5 9.1 a. Do the initial Se concentrations for the supplement and control samples appear to be similar? Use various techniques from this chapter to summarize the data and answer the question posed. b. Again use methods from this chapter to summarize the data and then describe how the final Se concentration values in the treatment group differ from those in the control group. 67. Aortic stenosis refers to a narrowing of the aortic valve in the heart. The paper “Correlation Analysis of Stenotic Aortic Valve Flow Patterns Using Phase Contrast MRI” Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 47 Supplementary Exercises (Annals of Biomed. Engr., 2005: 878–887) gave the following data on aortic root diameter (cm) and gender for a sample of patients having various degrees of aortic stenosis: M: 3.7 3.4 3.7 4.0 3.9 3.8 3.4 3.6 3.1 4.0 3.4 3.8 3.5 F: 3.8 2.6 3.2 3.0 4.3 3.5 3.1 3.1 3.2 3.0 a. Compare and contrast the diameter observations for the two genders. b. Calculate a 10% trimmed mean for each of the two samples, and compare to other measures of center (for the male sample, the interpolation method mentioned in Section 1.3 must be used). 68. a. For what value of c is the quantity g (xi 2 c)2 minimized? [Hint: Take the derivative with respect to c, set equal to 0, and solve.] b. Using the result of part (a), which of the two quantities g (xi 2 x)2 and g (xi 2 m)2 will be smaller than the other (assuming that x 2 m)? 69. a. Let a and b be constants and let yi 5 axi 1 b for i 5 1, 2, c, n. What are the relationships between x and y and between s 2x and s 2y? b. A sample of temperatures for initiating a certain chemical reaction yielded a sample average (°C) of 87.3 and a sample standard deviation of 1.04. What are the sample average and standard deviation measured in °F? [Hint: 9 F 5 C 1 32.] 5 70. Elevated energy consumption during exercise continues after the workout ends. Because calories burned after exercise contribute to weight loss and have other consequences, it is important to understand this process. The paper “Effect of Weight Training Exercise and Treadmill Exercise on Post-Exercise Oxygen Consumption” (Medicine and Science in Sports and Exercise, 1998: 518–522) reported the accompanying data from a study in which oxygen consumption (liters) was measured continuously for 30 minutes for each of 15 subjects both after a weight training exercise and after a treadmill exercise. Subject 1 2 3 4 5 6 7 Weight (x) 14.6 14.4 19.5 24.3 16.3 22.1 23.0 Treadmill (y) 11.3 5.3 9.1 15.2 10.1 19.6 20.8 Subject 8 9 10 11 12 13 14 15 Weight (x) 18.7 19.0 17.0 19.1 19.6 23.2 18.5 15.9 Treadmill (y) 10.3 10.3 2.6 16.6 22.4 23.6 12.6 4.4 a. Construct a comparative boxplot of the weight and treadmill observations, and comment on what you see. b. Because the data is in the form of (x, y) pairs, with x and y measurements on the same variable under two different conditions, it is natural to focus on the differences within pairs: d1 5 x1 2 y1, c, dn 5 xn 2 yn. Construct a boxplot of the sample differences. What does it suggest? 71. Here is a description from Minitab of the strength data given in Exercise 13. Variable N Mean Median TrMean StDev SE Mean strength 153 135.39 135.40 135.41 4.59 0.37 Variable strength Minimum 122.20 Maximum 147.70 Q1 132.95 Q3 138.25 a. Comment on any interesting features (the quartiles and fourths are virtually identical here). b. Construct a boxplot of the data based on the quartiles, and comment on what you see. 72. Anxiety disorders and symptoms can often be effectively treated with benzodiazepine medications. It is known that animals exposed to stress exhibit a decrease in benzodiazepine receptor binding in the frontal cortex. The paper “Decreased Benzodiazepine Receptor Binding in Prefrontal Cortex in Combat-Related Posttraumatic Stress Disorder” (Amer. J. of Psychiatry, 2000: 1120–1126) described the first study of benzodiazepine receptor binding in individuals suffering from PTSD. The accompanying data on a receptor binding measure (adjusted distribution volume) was read from a graph in the paper. PTSD: 10, 20, 25, 28, 31, 35, 37, 38, 38, 39, 39, 42, 46 Healthy: 23, 39, 40, 41, 43, 47, 51, 58, 63, 66, 67, 69, 72 Use various methods from this chapter to describe and summarize the data. 73. The article “Can We Really Walk Straight?” (Amer. J. of Physical Anthropology, 1992: 19–27) reported on an experiment in which each of 20 healthy men was asked to walk as straight as possible to a target 60 m away at normal speed. Consider the following observations on cadence (number of strides per second): .95 .78 .85 .93 .92 .93 .95 1.05 .93 .93 .86 1.06 1.00 1.06 .92 .96 .85 .81 .81 .96 Use the methods developed in this chapter to summarize the data; include an interpretation or discussion wherever appropriate. [Note: The author of the article used a rather sophisticated statistical analysis to conclude that people cannot walk in a straight line and suggested several explanations for this.] 74. The mode of a numerical data set is the value that occurs most frequently in the set. a. Determine the mode for the cadence data given in Exercise 73. b. For a categorical sample, how would you define the modal category? 75. Specimens of three different types of rope wire were selected, and the fatigue limit (MPa) was determined for each specimen, resulting in the accompanying data. Type 1 350 350 350 371 372 372 358 384 Type 2 350 354 359 363 373 374 376 380 370 370 370 371 391 391 392 365 368 369 383 388 392 371 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 48 CHAPTER 1 Type 3 Overview and Descriptive Statistics 350 361 362 364 364 365 366 371 377 377 377 379 380 380 392 a. Construct a comparative boxplot, and comment on similarities and differences. b. Construct a comparative dotplot (a dotplot for each sample with a common scale). Comment on similarities and differences. c. Does the comparative boxplot of part (a) give an informative assessment of similarities and differences? Explain your reasoning. 76. The three measures of center introduced in this chapter are the mean, median, and trimmed mean. Two additional measures of center that are occasionally used are the midrange, which is the average of the smallest and largest observations, and the midfourth, which is the average of the two fourths.Which of these five measures of center are resistant to the effects of outliers and which are not? Explain your reasoning. 77. The authors of the article “Predictive Model for Pitting Corrosion in Buried Oil and Gas Pipelines” (Corrosion, 2009: 332–342) provided the data on which their investigation was based. a. Consider the following sample of 61 observations on maximum pitting depth (mm) of pipeline specimens buried in clay loam soil. 0.41 0.58 1.02 1.17 1.68 2.49 4.75 0.41 0.79 1.04 1.19 1.91 2.57 5.33 0.41 0.79 1.04 1.19 1.96 2.74 7.65 0.41 0.81 1.17 1.27 1.96 3.10 7.70 0.43 0.43 0.43 0.81 0.81 0.91 1.17 1.17 1.17 1.40 1.40 1.59 1.96 2.10 2.21 3.18 3.30 3.58 8.13 10.41 13.44 0.48 0.94 1.17 1.59 2.31 3.58 0.48 0.94 1.17 1.60 2.46 4.15 Construct a stem-and-leaf display in which the two largest values are shown in a last row labeled HI. b. Refer back to (a), and create a histogram based on eight classes with 0 as the lower limit of the first class and class widths of .5, .5, .5, .5, 1, 2, 5, and 5, respectively. c. The accompanying comparative boxplot from Minitab shows plots of pitting depth for four different types of soils. Describe its important features. 78. Consider a sample x1, x2, c, xn and suppose that the values of x, s2, and s have been calculated. a. Let yi 5 xi 2 x for i 5 1, c, n. How do the values of s2 and s for the yi’s compare to the corresponding values for the xi’s? Explain. b. Let zi 5 (xi 2 x)/s for i 5 1, c, n. What are the values of the sample variance and sample standard deviation for the zi’s? 79. Let xn and s 2n denote the sample mean and variance for the sample x1, c, xn and let xn11 and s 2n11 denote these quantities when an additional observation xn11 is added to the sample. a. Show how xn11 can be computed from xn and xn11. b. Show that n (x 2 xn)2 n 1 1 n11 so that s 2n11 can be computed from xn11, xn, and s 2n. c. Suppose that a sample of 15 strands of drapery yarn has resulted in a sample mean thread elongation of 12.58 mm and a sample standard deviation of .512 mm. A 16th strand results in an elongation value of 11.8. What are the values of the sample mean and sample standard deviation for all 16 elongation observations? ns 2n11 5 (n 2 1)s 2n 1 80. Lengths of bus routes for any particular transit system will typically vary from one route to another. The article “Planning of City Bus Routes” (J. of the Institution of Engineers, 1995: 211–215) gives the following information on lengths (km) for one particular system: Length Frequency 62,8 6 82,10 102,12 122,14 142,16 23 30 35 32 162,18 182,20 202,22 222,24 242,26 Length Frequency 48 42 40 28 27 Length 262,28 282,30 302,35 352,40 402,45 Frequency 26 14 27 11 2 Comparative boxplot for Exercise 77 14 Maximum pit depth 12 10 8 6 4 2 0 C CL SCL SYCL Soil type Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Bibliography a. Draw a histogram corresponding to these frequencies. b. What proportion of these route lengths are less than 20? What proportion of these routes have lengths of at least 30? c. Roughly what is the value of the 90th percentile of the route length distribution? d. Roughly what is the median route length? 81. A study carried out to investigate the distribution of total braking time (reaction time plus accelerator-to-brake movement time, in ms) during real driving conditions at 60 km/hr gave the following summary information on the distribution of times (“A Field Study on Braking Responses During Driving,” Ergonomics, 1995: 1903–1910): mean 5 535 median 5 500 mode 5 500 sd 5 96 minimum 5 220 maximum 5 925 5th percentile 5 400 10th percentile 5 430 90th percentile 5 640 95th percentile 5 720 What can you conclude about the shape of a histogram of this data? Explain your reasoning. 82. The sample data x1, x2, c, xn sometimes represents a time series, where xt 5 the observed value of a response variable x at time t. Often the observed series shows a great deal of random variation, which makes it difficult to study longerterm behavior. In such situations, it is desirable to produce a smoothed version of the series. One technique for doing so involves exponential smoothing. The value of a smoothing constant a is chosen (0 , a , 1). Then with xt 5 smoothed value at time t, we set x1 5 x1, and for t 5 2, 3, c, n, xt 5 axt 1 (1 2 a)xt21. a. Consider the following time series in which xt 5 temperature (8F) of effluent at a sewage treatment plant on day t: 47, 54, 53, 50, 46, 46, 47, 50, 51, 50, 46, 52, 50, 50. Plot each xt against t on a two-dimensional coordinate system (a time-series plot). Does there appear to be any pattern? b. Calculate the x t ’s using a 5 .1. Repeat using a 5 .5. Which value of a gives a smoother xt series? 49 c. Substitute xt21 5 axt21 1 (1 2 a)xt22 on the right-hand side of the expression for xt, then substitute xt22 in terms of xt22 and xt23, and so on. On how many of the values xt, xt21, c, x1 does xt depend? What happens to the coefficient on xt2k as k increases? d. Refer to part (c). If t is large, how sensitive is xt to the initialization x1 5 x1? Explain. [Note: A relevant reference is the article “Simple Statistics for Interpreting Environmental Data,” Water Pollution Control Fed. J., 1981: 167–175.] 83. Consider numerical observations x1, c, xn. It is frequently of interest to know whether the xi s are (at least approximately) symmetrically distributed about some value. If n is at least moderately large, the extent of symmetry can be assessed from a stem-and-leaf display or histogram. However, if n is not very large, such pictures are not particularly informative. Consider the following alternative. Let y1 denote the smallest xi, y2 the second smallest xi, and so on. Then plot the following pairs as points on a two-dimensional coordinate system: (yn 2 | x, | x 2 y1), (yn21 2 | x, | x 2 y2), | | (yn22 2 x , x 2 y3), cThere are n/2 points when n is even and (n 2 1)/2 when n is odd. a. What does this plot look like when there is perfect symmetry in the data? What does it look like when observations stretch out more above the median than below it (a long upper tail)? b. The accompanying data on rainfall (acre-feet) from 26 seeded clouds is taken from the article “A Bayesian Analysis of a Multiplicative Treatment Effect in Weather Modification” (Technometrics, 1975: 161–166). Construct the plot and comment on the extent of symmetry or nature of departure from symmetry. 4.1 115.3 255.0 703.4 7.7 17.5 31.4 32.7 40.6 92.4 118.3 119.0 129.6 198.6 200.7 242.5 274.7 274.7 302.8 334.1 430.0 489.1 978.0 1656.0 1697.8 2745.6 Bibliography Chambers, John, William Cleveland, Beat Kleiner, and Paul Tukey, Graphical Methods for Data Analysis, Brooks/Cole, Pacific Grove, CA, 1983. A highly recommended presentation of various graphical and pictorial methodology in statistics. Cleveland, William, Visualizing Data, Hobart Press, Summit, NJ, 1993. An entertaining tour of pictorial techniques. Peck, Roxy, and Jay Devore, Statistics: The Exploration and Analysis of Data (6th ed.), Thomson Brooks/Cole, Belmont, CA, 2008. The first few chapters give a very nonmathematical survey of methods for describing and summarizing data. Freedman, David, Robert Pisani, and Roger Purves, Statistics (4th ed.), Norton, New York, 2007. An excellent, very nonmathematical survey of basic statistical reasoning and methodology. Hoaglin, David, Frederick Mosteller, and John Tukey, Understanding Robust and Exploratory Data Analysis, Wiley, New York, 1983. Discusses why, as well as how, exploratory methods should be employed; it is good on details of stem-and-leaf displays and boxplots. Moore, David, and William Notz, Statistics: Concepts and Controversies (7th ed.), Freeman, San Francisco, 2009. An extremely readable and entertaining paperback that contains an intuitive discussion of problems connected with sampling and designed experiments. Peck, Roxy, et al. (eds.), Statistics: A Guide to the Unknown (4th ed.), Thomson Brooks/Cole, Belmont, CA, 2006. Contains many short nontechnical articles describing various applications of statistics. Verzani, John, Using R for Introductory Statistics, Chapman and Hall/CRC, Boca Raton, FL, 2005. A very nice introduction to the R software package. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2 Probability INTRODUCTION The term probability refers to the study of randomness and uncertainty. In any situation in which one of a number of possible outcomes may occur, the discipline of probability provides methods for quantifying the chances, or likelihoods, associated with the various outcomes. The language of probability is constantly used in an informal manner in both written and spoken contexts. Examples include such statements as “It is likely that the Dow Jones average will increase by the end of the year,” “There is a 50–50 chance that the incumbent will seek reelection,” “There will probably be at least one section of that course offered next year,” “The odds favor a quick settlement of the strike,” and “It is expected that at least 20,000 concert tickets will be sold.” In this chapter, we introduce some elementary probability concepts, indicate how probabilities can be interpreted, and show how the rules of probability can be applied to compute the probabilities of many interesting events. The methodology of probability will then permit us to express in precise language such informal statements as those given above. The study of probability as a branch of mathematics goes back over 300 years, where it had its genesis in connection with questions involving games of chance. Many books are devoted exclusively to probability, but our objective here is to cover only that part of the subject that has the most direct bearing on problems of statistical inference. 50 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 51 2.1 Sample Spaces and Events 2.1 Sample Spaces and Events An experiment is any activity or process whose outcome is subject to uncertainty. Although the word experiment generally suggests a planned or carefully controlled laboratory testing situation, we use it here in a much wider sense. Thus experiments that may be of interest include tossing a coin once or several times, selecting a card or cards from a deck, weighing a loaf of bread, ascertaining the commuting time from home to work on a particular morning, obtaining blood types from a group of individuals, or measuring the compressive strengths of different steel beams. The Sample Space of an Experiment DEFINITION The sample space of an experiment, denoted by S , is the set of all possible outcomes of that experiment. Example 2.1 The simplest experiment to which probability applies is one with two possible outcomes. One such experiment consists of examining a single fuse to see whether it is defective. The sample space for this experiment can be abbreviated as S 5 5N, D6 , where N represents not defective, D represents defective, and the braces are used to enclose the elements of a set. Another such experiment would involve tossing a thumbtack and noting whether it landed point up or point down, with sample space S 5 5U, D6 , and yet another would consist of observing the gender of the next child born at the local hospital, with S 5 5M, F6 . ■ Example 2.2 If we examine three fuses in sequence and note the result of each examination, then an outcome for the entire experiment is any sequence of N’s and D’s of length 3, so S 5 5NNN, NND, NDN, NDD, DNN, DND, DDN, DDD6 If we had tossed a thumbtack three times, the sample space would be obtained by replacing N by U in S above, with a similar notational change yielding the sample space for the experiment in which the genders of three newborn children are observed. ■ Example 2.3 Two gas stations are located at a certain intersection. Each one has six gas pumps. Consider the experiment in which the number of pumps in use at a particular time of day is determined for each of the stations. An experimental outcome specifies how many pumps are in use at the first station and how many are in use at the second one. One possible outcome is (2, 2), another is (4, 1), and yet another is (1, 4). The 49 outcomes in S are displayed in the accompanying table. The sample space for the experiment in which a six-sided die is thrown twice results from deleting the 0 row and 0 column from the table, giving 36 outcomes. Second Station First Station 0 1 2 3 4 5 6 0 1 2 3 4 5 6 (0, 0) (1, 0) (2, 0) (3, 0) (4, 0) (5, 0) (6, 0) (0, 1) (1, 1) (2, 1) (3, 1) (4, 1) (5, 1) (6, 1) (0, 2) (1, 2) (2, 2) (3, 2) (4, 2) (5, 2) (6, 2) (0, 3) (1, 3) (2, 3) (3, 3) (4, 3) (5, 3) (6, 3) (0, 4) (1, 4) (2, 4) (3, 4) (4, 4) (5, 4) (6, 4) (0, 5) (1, 5) (2, 5) (3, 5) (4, 5) (5, 5) (6, 5) (0, 6) (1, 6) (2, 6) (3, 6) (4, 6) (5, 6) (6, 6) ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 52 CHAPTER 2 Probability Example 2.4 A reasonably large percentage of C⫹⫹ programs written at a particular company compile on the first run, but some do not (a compiler is a program that translates source code, in this case C⫹⫹ programs, into machine language so programs can be executed). Suppose an experiment consists of selecting and compiling C⫹⫹ programs at this location one by one until encountering a program that compiles on the first run. Denote a program that compiles on the first run by S (for success) and one that doesn’t do so by F (for failure). Although it may not be very likely, a possible outcome of this experiment is that the first 5 (or 10 or 20 or . . .) are F’s and the next one is an S. That is, for any positive integer n, we may have to examine n programs before seeing the first S. The sample space is S 5 5S, FS, FFS, FFFS, c6 , which contains an infinite number of possible outcomes. The same abbreviated form of the sample space is appropriate for an experiment in which, starting at a specified time, the gender of each newborn infant is recorded until the birth of a male is observed. ■ Events In our study of probability, we will be interested not only in the individual outcomes of S but also in various collections of outcomes from S . DEFINITION An event is any collection (subset) of outcomes contained in the sample space S . An event is simple if it consists of exactly one outcome and compound if it consists of more than one outcome. When an experiment is performed, a particular event A is said to occur if the resulting experimental outcome is contained in A. In general, exactly one simple event will occur, but many compound events will occur simultaneously. Example 2.5 Consider an experiment in which each of three vehicles taking a particular freeway exit turns left (L) or right (R) at the end of the exit ramp. The eight possible outcomes that comprise the sample space are LLL, RLL, LRL, LLR, LRR, RLR, RRL, and RRR. Thus there are eight simple events, among which are E1 5 5LLL6 and E5 5 5LRR6 . Some compound events include A 5 5RLL, LRL, LLR6 5 the event that exactly one of the three vehicles turns right B 5 5LLL, RLL, LRL, LLR6 5 the event that at most one of the vehicles turns right C 5 5LLL, RRR6 5 the event that all three vehicles turn in the same direction Suppose that when the experiment is performed, the outcome is LLL. Then the simple event E1 has occurred and so also have the events B and C (but not A). ■ Example 2.6 (Example 2.3 continued) When the number of pumps in use at each of two six-pump gas stations is observed, there are 49 possible outcomes, so there are 49 simple events: E1 5 5(0, 0)6, E2 5 5(0, 1)6, c, E49 5 5(6, 6)6 . Examples of compound events are Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Example 2.7 (Example 2.4 continued) 2.1 Sample Spaces and Events 53 A 5 5(0, 0), (1, 1), (2, 2), (3, 3), (4, 4), (5, 5), (6, 6)6 5 the event that the number of pumps in use is the same for both stations B 5 5(0, 4), (1, 3), (2, 2), (3, 1), (4, 0)6 5 the event that the total number of pumps in use is four C 5 5(0, 0), (0, 1), (1, 0), (1, 1)6 5 the event that at most one pump is in use at each station ■ The sample space for the program compilation experiment contains an infinite number of outcomes, so there are an infinite number of simple events. Compound events include A 5 5S, FS, FFS6 5 the event that at most three programs are examined E 5 5FS, FFFS, FFFFFS, c6 5 the event that an even number of programs are examined ■ Some Relations from Set Theory An event is just a set, so relationships and results from elementary set theory can be used to study events. The following operations will be used to create new events from given events. DEFINITION Example 2.8 (Example 2.3 continued) 1. The complement of an event A, denoted by Ar, is the set of all outcomes in S that are not contained in A. 2. The union of two events A and B, denoted by A ´ B and read “A or B,” is the event consisting of all outcomes that are either in A or in B or in both events (so that the union includes outcomes for which both A and B occur as well as outcomes for which exactly one occurs)—that is, all outcomes in at least one of the events. 3. The intersection of two events A and B, denoted by A ¨ B and read “A and B,” is the event consisting of all outcomes that are in both A and B. For the experiment in which the number of pumps in use at a single six-pump gas station is observed, let A 5 50, 1, 2, 3, 46 , B 5 53, 4, 5, 66 , and C 5 51, 3, 56 . Then Ar 5 55, 66, A ´ B 5 50, 1, 2, 3, 4, 5, 66 5 S, A ´ C 5 50, 1, 2, 3, 4, 56, ■ A ¨ B 5 53, 46, A ¨ C 5 51, 36, (A ¨ C)r 5 50, 2, 4, 5, 66 Example 2.9 (Example 2.4 continued) In the program compilation experiment, define A, B, and C by A 5 5S, FS, FFS6, B 5 5S, FFS, FFFFS6, C 5 5FS, FFFS, FFFFFS, c6 Then Ar 5 5FFFS, FFFFS, FFFFFS,c6, Cr 5 5S, FFS, FFFFS, c6 A ´ B 5 5S, FS, FFS, FFFFS6, A ¨ B 5 5S, FFS6 ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 54 CHAPTER 2 Probability Sometimes A and B have no outcomes in common, so that the intersection of A and B contains no outcomes. DEFINITION Example 2.10 Let [ denote the null event (the event consisting of no outcomes whatsoever). When A ¨ B 5 [, A and B are said to be mutually exclusive or disjoint events. A small city has three automobile dealerships: a GM dealer selling Chevrolets and Buicks; a Ford dealer selling Fords and Lincolns; and a Toyota dealer. If an experiment consists of observing the brand of the next car sold, then the events A 5 5Chevrolet, Buick6 and B 5 5Ford, Lincoln6 are mutually exclusive because the next car sold cannot be both a GM product and a Ford product (at least until the two companies merge!). ■ The operations of union and intersection can be extended to more than two events. For any three events A, B, and C, the event A ´ B ´ C is the set of outcomes contained in at least one of the three events, whereas A ¨ B ¨ C is the set of outcomes contained in all three events. Given events A1, A2, A3, c, these events are said to be mutually exclusive (or pairwise disjoint) if no two events have any outcomes in common. A pictorial representation of events and manipulations with events is obtained by using Venn diagrams. To construct a Venn diagram, draw a rectangle whose interior will represent the sample space S . Then any event A is represented as the interior of a closed curve (often a circle) contained in S . Figure 2.1 shows examples of Venn diagrams. A B A B A B A B A (a) Venn diagram of events A and B (b) Shaded region is A B (c) Shaded region is A B Figure 2.1 EXERCISES (d) Shaded region is A' (e) Mutually exclusive events Venn diagrams Section 2.1 (1–10) 1. Four universities—1, 2, 3, and 4—are participating in a holiday basketball tournament. In the first round, 1 will play 2 and 3 will play 4. Then the two winners will play for the championship, and the two losers will also play. One possible outcome can be denoted by 1324 (1 beats 2 and 3 beats 4 in first-round games, and then 1 beats 3 and 2 beats 4). a. List all outcomes in S . b. Let A denote the event that 1 wins the tournament. List outcomes in A. c. Let B denote the event that 2 gets into the championship game. List outcomes in B. d. What are the outcomes in A ´ B and in A ¨ B? What are the outcomes in A⬘? 2. Suppose that vehicles taking a particular freeway exit can turn right (R), turn left (L), or go straight (S). Consider observing the direction for each of three successive vehicles. a. List all outcomes in the event A that all three vehicles go in the same direction. b. List all outcomes in the event B that all three vehicles take different directions. c. List all outcomes in the event C that exactly two of the three vehicles turn right. d. List all outcomes in the event D that exactly two vehicles go in the same direction. e. List outcomes in D⬘, C ´ D, and C ¨ D. 3. Three components are connected to form a system as shown in the accompanying diagram. Because the components in the 2–3 subsystem are connected in parallel, that subsystem will function if at least one of the two individual components Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.2 Axioms, Interpretations, and Properties of Probability functions. For the entire system to function, component 1 must function and so must the 2–3 subsystem. 2 1 3 The experiment consists of determining the condition of each component [S (success) for a functioning component and F (failure) for a nonfunctioning component]. a. Which outcomes are contained in the event A that exactly two out of the three components function? b. Which outcomes are contained in the event B that at least two of the components function? c. Which outcomes are contained in the event C that the system functions? d. List outcomes in C⬘, A ´ C, A ¨ C, B ´ C, and B ¨ C. 4. Each of a sample of four home mortgages is classified as fixed rate (F) or variable rate (V). a. What are the 16 outcomes in S ? b. Which outcomes are in the event that exactly three of the selected mortgages are fixed rate? c. Which outcomes are in the event that all four mortgages are of the same type? d. Which outcomes are in the event that at most one of the four is a variable-rate mortgage? e. What is the union of the events in parts (c) and (d), and what is the intersection of these two events? f. What are the union and intersection of the two events in parts (b) and (c)? 5. A family consisting of three persons—A, B, and C—goes to a medical clinic that always has a doctor at each of stations 1, 2, and 3. During a certain week, each member of the family visits the clinic once and is assigned at random to a station. The experiment consists of recording the station number for each member. One outcome is (1, 2, 1) for A to station 1, B to station 2, and C to station 1. a. List the 27 outcomes in the sample space. b. List all outcomes in the event that all three members go to the same station. c. List all outcomes in the event that all members go to different stations. d. List all outcomes in the event that no one goes to station 2. 6. A college library has five copies of a certain text on reserve. Two copies (1 and 2) are first printings, and the other three (3, 4, 55 and 5) are second printings. A student examines these books in random order, stopping only when a second printing has been selected. One possible outcome is 5, and another is 213. a. List the outcomes in S . b. Let A denote the event that exactly one book must be examined. What outcomes are in A? c. Let B be the event that book 5 is the one selected. What outcomes are in B? d. Let C be the event that book 1 is not examined. What outcomes are in C? 7. An academic department has just completed voting by secret ballot for a department head. The ballot box contains four slips with votes for candidate A and three slips with votes for candidate B. Suppose these slips are removed from the box one by one. a. List all possible outcomes. b. Suppose a running tally is kept as slips are removed. For what outcomes does A remain ahead of B throughout the tally? 8. An engineering construction firm is currently working on power plants at three different sites. Let Ai denote the event that the plant at site i is completed by the contract date. Use the operations of union, intersection, and complementation to describe each of the following events in terms of A1, A2, and A3, draw a Venn diagram, and shade the region corresponding to each one. a. At least one plant is completed by the contract date. b. All plants are completed by the contract date. c. Only the plant at site 1 is completed by the contract date. d. Exactly one plant is completed by the contract date. e. Either the plant at site 1 or both of the other two plants are completed by the contract date. 9. Use Venn diagrams to verify the following two relationships for any events A and B (these are called De Morgan’s laws): a. (A ´ B)r 5 Ar ¨ Br b. (A ¨ B)r 5 Ar ´ Br [Hint: In each part, draw a diagram corresponding to the left side and another corresponding to the right side.] 10. a. In Example 2.10, identify three events that are mutually exclusive. b. Suppose there is no outcome common to all three of the events A, B, and C. Are these three events necessarily mutually exclusive? If your answer is yes, explain why; if your answer is no, give a counterexample using the experiment of Example 2.10. 2.2 Axioms, Interpretations, and Properties of Probability Given an experiment and a sample space S , the objective of probability is to assign to each event A a number P(A), called the probability of the event A, which will give a precise measure of the chance that A will occur. To ensure that the probability Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 56 CHAPTER 2 Probability assignments will be consistent with our intuitive notions of probability, all assignments should satisfy the following axioms (basic properties) of probability. AXIOM 1 AXIOM 2 AXIOM 3 For any event A, P(A) $ 0. P(S ) 5 1. If A1, A2, A3, c is an infinite collection of disjoint events, then ` P(A1 ´ A2 ´ A3 ´ c) 5 g P(Ai) i51 You might wonder why the third axiom contains no reference to a finite collection of disjoint events. It is because the corresponding property for a finite collection can be derived from our three axioms. We want our axiom list to be as short as possible and not contain any property that can be derived from others on the list. Axiom 1 reflects the intuitive notion that the chance of A occurring should be nonnegative. The sample space is by definition the event that must occur when the experiment is performed (S contains all possible outcomes), so Axiom 2 says that the maximum possible probability of 1 is assigned to S . The third axiom formalizes the idea that if we wish the probability that at least one of a number of events will occur and no two of the events can occur simultaneously, then the chance of at least one occurring is the sum of the chances of the individual events. PROPOSITION P([) 5 0 where [ is the null event (the event containing no outcomes whatsoever). This in turn implies that the property contained in Axiom 3 is valid for a finite collection of disjoint events. Proof First consider the infinite collection A1 5 [, A2 5 [, A3 5 [, c. Since [ ¨ [ 5 [, the events in this collection are disjoint and ´ Ai 5 [. The third axiom then gives P([) 5 gP([) This can happen only if P([) 5 0. Now suppose that A1, A2, c, Ak are disjoint events, and append to these the infinite collection Ak11 5 [, Ak12 5 [, Ak13 5 [, c. Again invoking the third axiom, Pa ´ Ai b 5 Pa ´ Ai b 5 k ` i51 i51 ` k i51 i51 g P(Ai) 5 g P(Ai) ■ as desired. Example 2.11 Consider tossing a thumbtack in the air. When it comes to rest on the ground, either its point will be up (the outcome U) or down (the outcome D). The sample space for this event is therefore S 5 5U, D6 . The axioms specify P(S ) 5 1, so the probability assignment will be completed by determining P(U) and P(D). Since U and D are disjoint and their union is S , the foregoing proposition implies that 1 5 P(S ) 5 P(U) 1 P(D) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.2 Axioms, Interpretations, and Properties of Probability 57 It follows that P(D) 5 1 2 P(U). One possible assignment of probabilities is P(U) 5 .5, P(D) 5 .5, whereas another possible assignment is P(U) 5 .75, P(D) 5 .25. In fact, letting p represent any fixed number between 0 and 1, P(U) 5 p, P(D) 5 1 2 p is an assignment consistent with the axioms. ■ Example 2.12 Consider testing batteries coming off an assembly line one by one until one having a voltage within prescribed limits is found. The simple events are E1 5 5S6, E2 5 5FS6, E3 5 5FFS6, E4 5 5FFFS6, c. Suppose the probability of any particular battery being satisfactory is .99. Then it can be shown that P(E1) 5 .99, P(E2) 5 (.01)(.99), P(E3) 5 (.01)2(.99), c is an assignment of probabilities to the simple events that satisfies the axioms. In particular, because the Eis are disjoint and S 5 E1 ´ E2 ´ E3 ´ c, it must be the case that 1 5 P(S) 5 P(E1) 1 P(E2) 1 P(E3) 1 c 5 .99[1 1 .01 1 (.01)2 1 (.01)3 1 c] Here we have used the formula for the sum of a geometric series: a 1 ar 1 ar2 1 ar3 1 c 5 a 12r However, another legitimate (according to the axioms) probability assignment of the same “geometric” type is obtained by replacing .99 by any other number p between 0 and 1 (and .01 by 1 2 p). ■ Interpreting Probability Examples 2.11 and 2.12 show that the axioms do not completely determine an assignment of probabilities to events. The axioms serve only to rule out assignments inconsistent with our intuitive notions of probability. In the tack-tossing experiment of Example 2.11, two particular assignments were suggested. The appropriate or correct assignment depends on the nature of the thumbtack and also on one’s interpretation of probability. The interpretation that is most frequently used and most easily understood is based on the notion of relative frequencies. Consider an experiment that can be repeatedly performed in an identical and independent fashion, and let A be an event consisting of a fixed set of outcomes of the experiment. Simple examples of such repeatable experiments include the tacktossing and die-tossing experiments previously discussed. If the experiment is performed n times, on some of the replications the event A will occur (the outcome will be in the set A), and on others, A will not occur. Let n(A) denote the number of replications on which A does occur. Then the ratio n(A)/n is called the relative frequency of occurrence of the event A in the sequence of n replications. For example, let A be the event that a package sent within the state of California for 2nd day delivery actually arrives within one day. The results from sending 10 such packages (the first 10 replications) are as follows: Package # 1 2 3 4 5 6 7 8 9 10 Did A occur? N Y Y Y N N Y Y N N Relative frequency of A 0 .5 .667 .75 .6 .5 .571 .625 .556 .5 Figure 2.2(a) shows how the relative frequency n(A)/n fluctuates rather substantially over the course of the first 50 replications. But as the number of replications continues to increase, Figure 2.2(b) illustrates how the relative frequency stabilizes. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 58 CHAPTER 2 Probability Relative frequency delivered in one day Relative frequency delivered in one day 1.0 Relative = 9 = .60 frequency 15 .8 .6 .4 Relative = 5 = .50 frequency 10 .2 .7 Approaches .6 .6 .5 0 0 10 20 30 40 Number of packages (a) Figure 2.2 50 0 100 200 300 400 500 600 700 Number of packages (b) 800 900 1000 Behavior of relative frequency (a) Initial fluctuation (b) Long-run stabilization More generally, empirical evidence, based on the results of many such repeatable experiments, indicates that any relative frequency of this sort will stabilize as the number of replications n increases. That is, as n gets arbitrarily large, n(A)/n approaches a limiting value referred to as the limiting (or long-run) relative frequency of the event A. The objective interpretation of probability identifies this limiting relative frequency with P(A). Suppose that probabilities are assigned to events in accordance with their limiting relative frequencies. Then a statement such as “the probability of a package being delivered within one day of mailing is .6” means that of a large number of mailed packages, roughly 60% will arrive within one day. Similarly, if B is the event that an appliance of a particular type will need service while under warranty, then P(B) 5 .1 is interpreted to mean that in the long run 10% of such appliances will need warranty service. This doesn’t mean that exactly 1 out of 10 will need service, or that exactly 10 out of 100 will need service, because 10 and 100 are not the long run. This relative frequency interpretation of probability is said to be objective because it rests on a property of the experiment rather than on any particular individual concerned with the experiment. For example, two different observers of a sequence of coin tosses should both use the same probability assignments since the observers have nothing to do with limiting relative frequency. In practice, this interpretation is not as objective as it might seem, since the limiting relative frequency of an event will not be known. Thus we will have to assign probabilities based on our beliefs about the limiting relative frequency of events under study. Fortunately, there are many experiments for which there will be a consensus with respect to probability assignments. When we speak of a fair coin, we shall mean P(H) 5 P(T) 5 .5, and a fair die is one for which limiting relative frequencies of the six outcomes are 1 1 all 6, suggesting probability assignments P(516) 5 c 5 P(566) 5 6. Because the objective interpretation of probability is based on the notion of limiting frequency, its applicability is limited to experimental situations that are repeatable. Yet the language of probability is often used in connection with situations Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.2 Axioms, Interpretations, and Properties of Probability 59 that are inherently unrepeatable. Examples include: “The chances are good for a peace agreement”; “It is likely that our company will be awarded the contract”; and “Because their best quarterback is injured, I expect them to score no more than 10 points against us.” In such situations we would like, as before, to assign numerical probabilities to various outcomes and events (e.g., the probability is .9 that we will get the contract). We must therefore adopt an alternative interpretation of these probabilities. Because different observers may have different prior information and opinions concerning such experimental situations, probability assignments may now differ from individual to individual. Interpretations in such situations are thus referred to as subjective. The book by Robert Winkler listed in the chapter references gives a very readable survey of several subjective interpretations. More Probability Properties PROPOSITION For any event A, P(A) 1 P(Ar) 5 1, from which P(A) 5 1 2 P(Ar). Proof In Axiom 3, let k 5 2, A1 5 A, and A2 5 Ar. Since by definition of A⬘, A ´ Ar 5 S while A and A⬘ are disjoint, 1 5 P(S ) 5 P(A ´ Ar) 5 P(A) 1 P(Ar). ■ This proposition is surprisingly useful because there are many situations in which P(Ar) is more easily obtained by direct methods than is P(A). Example 2.13 Consider a system of five identical components connected in series, as illustrated in Figure 2.3. 1 Figure 2.3 2 3 4 5 A system of five components connected in a series Denote a component that fails by F and one that doesn’t fail by S (for success). Let A be the event that the system fails. For A to occur, at least one of the individual components must fail. Outcomes in A include SSFSS (1, 2, 4, and 5 all work, but 3 does not), FFSSS, and so on. There are in fact 31 different outcomes in A. However, A⬘, the event that the system works, consists of the single outcome SSSSS. We will see in Section 2.5 that if 90% of all such components do not fail and different components fail independently of one another, then P(Ar) 5 P(SSSSS) 5 .95 5 .59. Thus P(A) 5 1 2 .59 5 .41; so among a large number of such systems, roughly 41% will fail. ■ In general, the foregoing proposition is useful when the event of interest can be expressed as “at least . . . ,” since then the complement “less than . . .” may be easier to work with (in some problems, “more than . . .” is easier to deal with than “at most . . .”). When you are having difficulty calculating P(A) directly, think of determining P(Ar). PROPOSITION For any event A, P(A) # 1. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 60 CHAPTER 2 Probability This is because 1 5 P(A) 1 P(Ar) $ P(A) since P(Ar) $ 0. When events A and B are mutually exclusive, P(A ´ B) 5 P(A) 1 P(B). For events that are not mutually exclusive, adding P(A) and P(B) results in “doublecounting” outcomes in the intersection. The next result shows how to correct for this. PROPOSITION For any two events A and B, P(A ´ B) 5 P(A) 1 P(B) 2 P(A ¨ B) Proof Note first that A ´ B can be decomposed into two disjoint events, A and B ¨ Ar; the latter is the part of B that lies outside A (see Figure 2.4). Furthermore, B itself is the union of the two disjoint events A ¨ B and Ar ¨ B, so P(B) 5 P(A ¨ B) 1 P(Ar ¨ B). Thus P(A ´ B) 5 P(A) 1 P(B ¨ Ar) 5 P(A) 1 [P(B) 2 P(A ¨ B)] 5 P(A) 1 P(B) 2 P(A ¨ B) A B Figure 2.4 Example 2.14 Representing A B as a union of disjoint events ■ In a certain residential suburb, 60% of all households get Internet service from the local cable company, 80% get television service from that company, and 50% get both services from that company. If a household is randomly selected, what is the probability that it gets at least one of these two services from the company, and what is the probability that it gets exactly one of these services from the company? With A 5 5gets Internet service6 and B 5 5gets TV service6 , the given information implies that P(A) 5 .6, P(B) 5 .8, and P(A ¨ B) 5 .5. The foregoing proposition now yields P(subscribes to at least one of the two services) 5 P(A ´ B) 5 P(A) 1 P(B) 2 P(A ¨ B) 5 .6 1 .8 2 .5 5 .9 The event that a household subscribes only to tv service can be written as Ar ¨ B [(not Internet) and TV]. Now Figure 2.4 implies that .9 5 P(A ´ B) 5 P(A) 1 P(Ar ¨ B) 5 .6 1 P(Ar ¨ B) from which P(Ar ¨ B) 5 .3. Similarly, P(A ¨ Br) 5 P(A ´ B) 2 P(B) 5 .1. This is all illustrated in Figure 2.5, from which we see that P(exactly one) 5 P(A ¨ Br) 1 P(Ar ¨ B) 5 .1 1 .3 5 .4 P(A' B) P(A B' ) .1 .5 Figure 2.5 .3 Probabilities for Example 2.14 ■ The probability of a union of more than two events can be computed analogously. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.2 Axioms, Interpretations, and Properties of Probability 61 For any three events A, B, and C, P(A ´ B ´ C) 5 P(A) 1 P(B) 1 P(C) 2 P(A ¨ B) 2 P(A ¨ C) 2P(B ¨ C) 1 P(A ¨ B ¨ C) This can be verified by examining a Venn diagram of A ´ B ´ C, which is shown in Figure 2.6. When P(A), P(B), and P(C) are added, certain intersections are counted twice, so they must be subtracted out, but this results in P(A ¨ B ¨ C) being subtracted once too often. B A C Figure 2.6 A´B´C Determining Probabilities Systematically Consider a sample space that is either finite or “countably infinite” (the latter means that outcomes can be listed in an infinite sequence, so there is a first outcome, a second outcome, a third outcome, and so on—for example, the battery testing scenario of Example 2.12). Let E1, E2, E3, c denote the corresponding simple events, each consisting of a single outcome. A sensible strategy for probability computation is to first determine each simple event probability, with the requirement that gP(Ei) 5 1. Then the probability of any compound event A is computed by adding together the P(E i)’s for all Ei’s in A: g P(E i) P(A) 5 all Ei ’s in A Example 2.15 During off-peak hours a commuter train has five cars. Suppose a commuter is twice as likely to select the middle car (#3) as to select either adjacent car (#2 or #4), and is twice as likely to select either adjacent car as to select either end car (#1 or #5). Let pi 5 P(car i is selected) 5 P(Ei). Then we have p3 5 2p2 5 2p4 and p2 5 2p1 5 2p5 5 p4. This gives 1 5 gP(Ei) 5 p1 1 2p1 1 4p1 1 2p1 1 p1 5 10p1 implying p1 5 p5 5 .1, p2 5 p4 5 .2, p3 5 .4. The probability that one of the three middle cars is selected (a compound event) is then p2 1 p3 1 p4 5 .8. ■ Equally Likely Outcomes In many experiments consisting of N outcomes, it is reasonable to assign equal probabilities to all N simple events. These include such obvious examples as tossing a fair coin or fair die once or twice (or any fixed number of times), or selecting one or several cards from a well-shuffled deck of 52. With p 5 P(Ei) for every i, 15 N N i51 i51 g P(Ei) 5 g p 5 p # N so p 5 1 N That is, if there are N equally likely outcomes, the probability for each is 1/N. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 62 CHAPTER 2 Probability Now consider an event A, with N(A) denoting the number of outcomes contained in A. Then P(A) 5 1 N(A) 5 N N Ei in A g P(Ei) 5 g Ei in A Thus when outcomes are equally likely, computing probabilities reduces to counting: determine both the number of outcomes N(A) in A and the number of outcomes N in S , and form their ratio. Example 2.16 You have six unread mysteries on your bookshelf and six unread science fiction books. The first three of each type are hardcover, and the last three are paperback. Consider randomly selecting one of the six mysteries and then randomly selecting one of the six science fiction books to take on a post-finals vacation to Acapulco (after all, you need something to read on the beach). Number the mysteries 1, 2, . . . , 6, and do the same for the science fiction books. Then each outcome is a pair of numbers such as (4, 1), and there are N 5 36 possible outcomes (For a visual of this situation, refer to the table in Example 2.3 and delete the first row and column). With random selection as described, the 36 outcomes are equally likely. Nine of these outcomes are such that both selected books are paperbacks (those in the lower right-hand corner of the referenced table): (4,4), (4,5), . . . , (6,6). So the probability of the event A that both selected books are paperbacks is P(A) 5 EXERCISES Intermediate bond Long bond ■ Section 2.2 (11–28) 11. A mutual fund company offers its customers a variety of funds: a money-market fund, three different bond funds (short, intermediate, and long-term), two stock funds (moderate and high-risk), and a balanced fund. Among customers who own shares in just one fund, the percentages of customers in the different funds are as follows: Money-market Short bond N(A) 9 5 5 .25 N 36 20% 15% High-risk stock Moderate-risk stock Balanced 18% 25% 7% 10% 5% A customer who owns shares in just one fund is randomly selected. a. What is the probability that the selected individual owns shares in the balanced fund? b. What is the probability that the individual owns shares in a bond fund? c. What is the probability that the selected individual does not own shares in a stock fund? 12. Consider randomly selecting a student at a certain university, and let A denote the event that the selected individual has a Visa credit card and B be the analogous event for a MasterCard. Suppose that P(A) 5 .5, P(B) 5 .4, and P(A ¨ B) 5 .25. a. Compute the probability that the selected individual has at least one of the two types of cards (i.e., the probability of the event A ´ B). b. What is the probability that the selected individual has neither type of card? c. Describe, in terms of A and B, the event that the selected student has a Visa card but not a MasterCard, and then calculate the probability of this event. 13. A computer consulting firm presently has bids out on three projects. Let Ai 5 5awarded project i6 , for i 5 1, 2, 3, and suppose that P(A1) 5 .22, P(A2) 5 .25, P(A3) 5 .28, P(A1 ¨ A2) 5 .11, P(A1 ¨ A3) 5 .05, P(A2 ¨ A3) 5 .07, P(A1 ¨ A2 ¨ A3) 5 .01. Express in words each of the following events, and compute the probability of each event: a. A1 ´ A2 b. Ar1 ¨ Ar2 [Hint: (A1 ´ A2)r 5 Ar1 ¨ Ar2] c. A1 ´ A2 ´ A3 d. Ar1 ¨ Ar2 ¨ Ar3 e. Ar1 ¨ Ar2 ¨ A3 f. (Ar1 ¨ Ar2 ) ´ A3 14. Suppose that 55% of all adults regularly consume coffee, 45% regularly consume carbonated soda, and 70% regularly consume at least one of these two products. a. What is the probability that a randomly selected adult regularly consumes both coffee and soda? b. What is the probability that a randomly selected adult doesn’t regularly consume at least one of these two products? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.2 Axioms, Interpretations, and Properties of Probability 15. Consider the type of clothes dryer (gas or electric) purchased by each of five different customers at a certain store. a. If the probability that at most one of these purchases an electric dryer is .428, what is the probability that at least two purchase an electric dryer? b. If P(all five purchase gas) 5 .116 and P(all five purchase electric) 5 .005, what is the probability that at least one of each type is purchased? 16. An individual is presented with three different glasses of cola, labeled C, D, and P. He is asked to taste all three and then list them in order of preference. Suppose the same cola has actually been put into all three glasses. a. What are the simple events in this ranking experiment, and what probability would you assign to each one? b. What is the probability that C is ranked first? c. What is the probability that C is ranked first and D is ranked last? 17. Let A denote the event that the next request for assistance from a statistical software consultant relates to the SPSS package, and let B be the event that the next request is for help with SAS. Suppose that P(A) 5 .30 and P(B) 5 .50. a. Why is it not the case that P(A) 1 P(B) 5 1? b. Calculate P(Ar). c. Calculate P(A ´ B). d. Calculate P(Ar ¨ Br). 18. A box contains six 40-W bulbs, five 60-W bulbs, and four 75-W bulbs. If bulbs are selected one by one in random order, what is the probability that at least two bulbs must be selected to obtain one that is rated 75 W? 19. Human visual inspection of solder joints on printed circuit boards can be very subjective. Part of the problem stems from the numerous types of solder defects (e.g., pad nonwetting, knee visibility, voids) and even the degree to which a joint possesses one or more of these defects. Consequently, even highly trained inspectors can disagree on the disposition of a particular joint. In one batch of 10,000 joints, inspector A found 724 that were judged defective, inspector B found 751 such joints, and 1159 of the joints were judged defective by at least one of the inspectors. Suppose that one of the 10,000 joints is randomly selected. a. What is the probability that the selected joint was judged to be defective by neither of the two inspectors? b. What is the probability that the selected joint was judged to be defective by inspector B but not by inspector A? 20. A certain factory operates three different shifts. Over the last year, 200 accidents have occurred at the factory. Some of these can be attributed at least in part to unsafe working conditions, whereas the others are unrelated to working conditions. The accompanying table gives the percentage of accidents falling in each type of accident– shift category. Shift Unsafe Conditions Unrelated to Conditions 10% 8% 5% 35% 20% 22% Day Swing Night 63 Suppose one of the 200 accident reports is randomly selected from a file of reports, and the shift and type of accident are determined. a. What are the simple events? b. What is the probability that the selected accident was attributed to unsafe conditions? c. What is the probability that the selected accident did not occur on the day shift? 21. An insurance company offers four different deductible levels—none, low, medium, and high—for its homeowner’s policyholders and three different levels—low, medium, and high—for its automobile policyholders. The accompanying table gives proportions for the various categories of policyholders who have both types of insurance. For example, the proportion of individuals with both low homeowner’s deductible and low auto deductible is .06 (6% of all such individuals). Homeowner’s Auto N L M H L M H .04 .07 .02 .06 .10 .03 .05 .20 .15 .03 .10 .15 Suppose an individual having both types of policies is randomly selected. a. What is the probability that the individual has a medium auto deductible and a high homeowner’s deductible? b. What is the probability that the individual has a low auto deductible? A low homeowner’s deductible? c. What is the probability that the individual is in the same category for both auto and homeowner’s deductibles? d. Based on your answer in part (c), what is the probability that the two categories are different? e. What is the probability that the individual has at least one low deductible level? f. Using the answer in part (e), what is the probability that neither deductible level is low? 22. The route used by a certain motorist in commuting to work contains two intersections with traffic signals. The probability that he must stop at the first signal is .4, the analogous probability for the second signal is .5, and the probability that he must stop at at least one of the two signals is .6. What is the probability that he must stop a. At both signals? b. At the first signal but not at the second one? c. At exactly one signal? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 64 CHAPTER 2 Probability 23. The computers of six faculty members in a certain department are to be replaced. Two of the faculty members have selected laptop machines and the other four have chosen desktop machines. Suppose that only two of the setups can be done on a particular day, and the two computers to be set up are randomly selected from the six (implying 15 equally likely outcomes; if the computers are numbered 1, 2, . . . , 6, then one outcome consists of computers 1 and 2, another consists of computers 1 and 3, and so on). a. What is the probability that both selected setups are for laptop computers? b. What is the probability that both selected setups are desktop machines? c. What is the probability that at least one selected setup is for a desktop computer? d. What is the probability that at least one computer of each type is chosen for setup? 24. Show that if one event A is contained in another event B (i.e., A is a subset of B), then P(A) # P(B). [Hint: For such A and B, A and B ¨ Ar are disjoint and B 5 A ´ (B ¨ Ar), as can be seen from a Venn diagram.] For general A and B, what does this imply about the relationship among P(A ¨ B), P(A) and P(A ´ B)? 25. The three most popular options on a certain type of new car are a built-in GPS (A), a sunroof (B), and an automatic transmission (C). If 40% of all purchasers request A, 55% request B, 70% request C, 63% request A or B, 77% request A or C, 80% request B or C, and 85% request A or B or C, determine the probabilities of the following events. [Hint: “A or B” is the event that at least one of the two options is requested; try drawing a Venn diagram and labeling all regions.] a. The next purchaser will request at least one of the three options. b. The next purchaser will select none of the three options. c. The next purchaser will request only an automatic transmission and not either of the other two options. d. The next purchaser will select exactly one of these three options. 26. A certain system can experience three different types of defects. Let Ai (i 5 1,2,3) denote the event that the system has a defect of type i. Suppose that P(A1) 5 .12 P(A2) 5 .07 P(A3) 5 .05 P(A1 ´ A2) 5 .13 P(A1 ´ A3) 5 .14 P(A2 ´ A3) 5 .10 P(A1 ¨ A2 ¨ A3) 5 .01 a. What is the probability that the system does not have a type 1 defect? b. What is the probability that the system has both type 1 and type 2 defects? c. What is the probability that the system has both type 1 and type 2 defects but not a type 3 defect? d. What is the probability that the system has at most two of these defects? 27. An academic department with five faculty members— Anderson, Box, Cox, Cramer, and Fisher—must select two of its members to serve on a personnel review committee. Because the work will be time-consuming, no one is anxious to serve, so it is decided that the representative will be selected by putting the names on identical pieces of paper and then randomly selecting two. a. What is the probability that both Anderson and Box will be selected? [Hint: List the equally likely outcomes.] b. What is the probability that at least one of the two members whose name begins with C is selected? c. If the five faculty members have taught for 3, 6, 7, 10, and 14 years, respectively, at the university, what is the probability that the two chosen representatives have a total of at least 15 years’ teaching experience there? 28. In Exercise 5, suppose that any incoming individual is equally likely to be assigned to any of the three stations irrespective of where other individuals have been assigned. What is the probability that a. All three family members are assigned to the same station? b. At most two family members are assigned to the same station? c. Every family member is assigned to a different station? 2.3 Counting Techniques When the various outcomes of an experiment are equally likely (the same probability is assigned to each simple event), the task of computing probabilities reduces to counting. Letting N denote the number of outcomes in a sample space and N(A) represent the number of outcomes contained in an event A, P(A) 5 N(A) N (2.1) If a list of the outcomes is easily obtained and N is small, then N and N(A) can be determined without the benefit of any general counting principles. There are, however, many experiments for which the effort involved in constructing such a list is prohibitive because N is quite large. By exploiting some Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.3 Counting Techniques 65 general counting rules, it is possible to compute probabilities of the form (2.1) without a listing of outcomes. These rules are also useful in many problems involving outcomes that are not equally likely. Several of the rules developed here will be used in studying probability distributions in the next chapter. The Product Rule for Ordered Pairs Our first counting rule applies to any situation in which a set (event) consists of ordered pairs of objects and we wish to count the number of such pairs. By an ordered pair, we mean that, if O1 and O2 are objects, then the pair (O1, O2) is different from the pair (O2, O1). For example, if an individual selects one airline for a trip from Los Angeles to Chicago and (after transacting business in Chicago) a second one for continuing on to New York, one possibility is (American, United), another is (United, American), and still another is (United, United). PROPOSITION If the first element or object of an ordered pair can be selected in n1 ways, and for each of these n1 ways the second element of the pair can be selected in n2 ways, then the number of pairs is n1n2. An alternative interpretation involves carrying out an operation that consists of two stages. If the first stage can be performed in any one of n1 ways, and for each such way there are n2 ways to perform the second stage, then n1n2 is the number of ways of carrying out the two stages in sequence. Example 2.17 A homeowner doing some remodeling requires the services of both a plumbing contractor and an electrical contractor. If there are 12 plumbing contractors and 9 electrical contractors available in the area, in how many ways can the contractors be chosen? If we denote the plumbers by P1, . . . , P12 and the electricians by Q1, . . . , Q9, then we wish the number of pairs of the form (Pi, Qj). With n1 5 12 and n2 5 9, the product rule yields N 5 (12)(9) 5 108 possible ways of choosing the two types of contractors. ■ In Example 2.17, the choice of the second element of the pair did not depend on which first element was chosen or occurred. As long as there is the same number of choices of the second element for each first element, the product rule is valid even when the set of possible second elements depends on the first element. Example 2.18 A family has just moved to a new city and requires the services of both an obstetrician and a pediatrician. There are two easily accessible medical clinics, each having two obstetricians and three pediatricians. The family will obtain maximum health insurance benefits by joining a clinic and selecting both doctors from that clinic. In how many ways can this be done? Denote the obstetricians by O1, O2, O3, and O4 and the pediatricians by P1, . . . , P6. Then we wish the number of pairs (Oi, Pj) for which Oi and Pj are associated with the same clinic. Because there are four obstetricians, n1 5 4, and for each there are three choices of pediatrician, so n2 5 3. Applying the product rule gives N 5 n1n2 5 12 possible choices. ■ In many counting and probability problems, a configuration called a tree diagram can be used to represent pictorially all the possibilities. The tree diagram associated with Example 2.18 appears in Figure 2.7. Starting from a point on the left side of the Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 66 CHAPTER 2 Probability diagram, for each possible first element of a pair a straight-line segment emanates rightward. Each of these lines is referred to as a first-generation branch. Now for any given first-generation branch we construct another line segment emanating from the tip of the branch for each possible choice of a second element of the pair. Each such line segment is a second-generation branch. Because there are four obstetricians, there are four first-generation branches, and three pediatricians for each obstetrician yields three second-generation branches emanating from each first-generation branch. P1 P2 O1 P1 P3 P2 O2 P3 O3 P4 P5 O4 P4 P6 P5 P6 Figure 2.7 Tree diagram for Example 2.18 Generalizing, suppose there are n1 first-generation branches, and for each firstgeneration branch there are n2 second-generation branches. The total number of second-generation branches is then n1n2. Since the end of each second-generation branch corresponds to exactly one possible pair (choosing a first element and then a second puts us at the end of exactly one second-generation branch), there are n1n2 pairs, verifying the product rule. The construction of a tree diagram does not depend on having the same number of second-generation branches emanating from each first-generation branch. If the second clinic had four pediatricians, then there would be only three branches emanating from two of the first-generation branches and four emanating from each of the other two first-generation branches. A tree diagram can thus be used to represent pictorially experiments other than those to which the product rule applies. A More General Product Rule If a six-sided die is tossed five times in succession rather than just twice, then each possible outcome is an ordered collection of five numbers such as (1, 3, 1, 2, 4) or (6, 5, 2, 2, 2). We will call an ordered collection of k objects a k-tuple (so a pair is a 2-tuple and a triple is a 3-tuple). Each outcome of the die-tossing experiment is then a 5-tuple. Product Rule for k-Tuples Suppose a set consists of ordered collections of k elements (k-tuples) and that there are n1 possible choices for the first element; for each choice of the first element, there are n2 possible choices of the second element; . . . ; for each possible choice of the first k 2 1 elements, there are nk choices of the kth element. Then there are n1n2 # c # nk possible k-tuples. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.3 Counting Techniques 67 An alternative interpretation involves carrying out an operation in k stages. If the first stage can be performed in any one of n1 ways, and for each such way there are n2 ways to perform the second stage, and for each way of performing the first two stages there are n3 ways to perform the 3rd stage, and so on, then n1n2 # c # nk is the number of ways to carry out the entire k-stage operation in sequence. This more general rule can also be visualized with a tree diagram. For the case k 5 3, simply add an appropriate number of 3rd generation branches to the tip of each 2nd generation branch. If, for example, a college town has four pizza places, a theater complex with six screens, and three places to go dancing, then there would be four 1st generation branches, six 2nd generation branches emanating from the tip of each 1st generation branch, and three 3rd generation branches leading off each 2nd generation branch. Each possible 3-tuple corresponds to the tip of a 3rd generation branch. Example 2.19 (Example 2.17 continued) Example 2.20 (Example 2.18 continued) Suppose the home remodeling job involves first purchasing several kitchen appliances. They will all be purchased from the same dealer, and there are five dealers in the area. With the dealers denoted by D1, . . . , D5, there are N 5 n1n2n3 5 (5)(12)(9) 5 540 3-tuples of the form (Di, Pj, Qk), so there are 540 ways to choose first an appliance dealer, then a plumbing contractor, and finally an electrical contractor. ■ If each clinic has both three specialists in internal medicine and two general surgeons, there are n1n2n3n4 5 (4)(3)(3)(2) 5 72 ways to select one doctor of each type such that all doctors practice at the same clinic. ■ Permutations and Combinations Consider a group of n distinct individuals or objects (“distinct” means that there is some characteristic that differentiates any particular individual or object from any other). How many ways are there to select a subset of size k from the group? For example, if a Little League team has 15 players on its roster, how many ways are there to select 9 players to form a starting lineup? Or if a university bookstore sells ten different laptop computers but has room to display only three of them, in how many ways can the three be chosen? An answer to the general question just posed requires that we distinguish between two cases. In some situations, such as the baseball scenario, the order of selection is important. For example, Angela being the pitcher and Ben the catcher gives a different lineup from the one in which Angela is catcher and Ben is pitcher. Often, though, order is not important and one is interested only in which individuals or objects are selected, as would be the case in the laptop display scenario. DEFINITION An ordered subset is called a permutation. The number of permutations of size k that can be formed from the n individuals or objects in a group will be denoted by Pk,n. An unordered subset is called a combination. One way to denote the number of combinations is Ck,n, but we shall instead use notation that is quite common in probability books: A nk B , read “n choose k”. The number of permutations can be determined by using our earlier counting rule for k-tuples. Suppose, for example, that a college of engineering has seven departments, which we denote by a, b, c, d, e, f, and g. Each department has one representative on the college’s student council. From these seven representatives, one is Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 68 CHAPTER 2 Probability to be chosen chair, another is to be selected vice-chair, and a third will be secretary. How many ways are there to select the three officers? That is, how many permutations of size 3 can be formed from the 7 representatives? To answer this question, think of forming a triple (3-tuple) in which the first element is the chair, the second is the vice-chair, and the third is the secretary. One such triple is (a, g, b), another is (b, g, a), and yet another is (d, f, b). Now the chair can be selected in any of n1 5 7 ways. For each way of selecting the chair, there are n2 5 6 ways to select the vicechair, and hence 7 3 6 5 42 (chair, vice-chair) pairs. Finally, for each way of selecting a chair and vice-chair, there are n3 5 5 ways of choosing the secretary. This gives P3, 7 5 (7)(6)(5) 5 210 as the number of permutations of size 3 that can be formed from 7 distinct individuals. A tree diagram representation would show three generations of branches. The expression for P3,7 can be rewritten with the aid of factorial notation. Recall that 7! (read “7 factorial”) is compact notation for the descending product of integers (7)(6)(5)(4)(3)(2)(1). More generally, for any positive integer m, . This gives 1! 5 1, and we also define m! 5 m(m 2 1)(m 2 2) # c # (2)(1) 0! 5 1. Then P3, 7 5 (7)(6)(5) 5 (7)(6)(5)(4!) 7! 5 (4!) 4! More generally, Pk, n 5 n(n 2 1)(n 2 2) # c # (n 2 (k 2 2))(n 2 (k 2 1)) Multiplying and dividing this by (n 2 k)! gives a compact expression for the number of permutations. PROPOSITION Example 2.21 Pk, n 5 n! (n 2 k)! There are ten teaching assistants available for grading papers in a calculus course at a large university. The first exam consists of four questions, and the professor wishes to select a different assistant to grade each question (only one assistant per question). In how many ways can the assistants be chosen for grading? Here n 5 group size 5 10 and k 5 subset size 5 4. The number of permutations is P4,10 5 10! 10! 5 5 10(9)(8)(7) 5 5040 (10 2 4)! 6! That is, the professor could give 5040 different four-question exams without using the same assignment of graders to questions, by which time all the teaching assistants would hopefully have finished their degree programs! ■ Now let’s move on to combinations (i.e., unordered subsets). Again refer to the student council scenario, and suppose that three of the seven representatives are to be selected to attend a statewide convention. The order of selection is not important; all that matters is which three get selected. So we are looking for A 73 B , the number of combinations of size 3 that can be formed from the 7 individuals. Consider for a Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.3 Counting Techniques 69 moment the combination a,c,g. These three individuals can be ordered in 3! 5 6 ways to produce permutations: a, c, g a, g, c c, a, g c, g, a g, a, c g, c, a Similarly, there are 3! 5 6 ways to order the combination b,c,e to produce permutations, and in fact 3! ways to order any particular combination of size 3 to produce permutations. This implies the following relationship between the number of combinations and the number of permutations: P3, 7 7! (7)(6)(5) 7 7 P3, 7 5 (3!) ? Q R 1 Q R 5 5 5 5 35 3 3 3! (3!)(4!) (3)(2)(1) It would not be too difficult to list the 35 combinations, but there is no need to do so if we are interested only in how many there are. Notice that the number of permutations 210 far exceeds the number of combinations; the former is larger than the latter by a factor of 3! since that is how many ways each combination can be ordered. Generalizing the foregoing line of reasoning gives a simple relationship between the number of permutations and the number of combinations that yields a concise expression for the latter quantity. PROPOSITION Pk,n n! n 5 Q R5 k k! k!(n 2 k)! Notice that A nn B 5 1 and A n0 B 5 1 since there is only one way to choose a set of (all) n elements or of no elements, and A n1 B 5 n since there are n subsets of size 1. Example 2.22 A particular iPod playlist contains 100 songs, 10 of which are by the Beatles. Suppose the shuffle feature is used to play the songs in random order (the randomness of the shuffling process is investigated in “Does Your iPod Really Play Favorites?” (The Amer. Statistician, 2009: 263–268). What is the probability that the first Beatles song heard is the fifth song played? In order for this event to occur, it must be the case that the first four songs played are not Beatles’ songs (NBs) and that the fifth song is by the Beatles (B). The number of ways to select the first five songs is 100(99)(98)(97)(96). The number of ways to select these five songs so that the first four are NBs and the next is a B is 90(89)(88)(87)(10). The random shuffle assumption implies that any particular set of 5 songs from amongst the 100 has the same chance of being selected as the first five played as does any other set of five songs; each outcome is equally likely. Therefore the desired probability is the ratio of the number of outcomes for which the event of interest occurs to the number of possible outcomes: P(1st B is the 5th song played) 5 P4, 90 # (10) 90 # 89 # 88 # 87 # 10 5 5 .0679 100 # 99 # 98 # 97 # 96 P5, 100 Here is an alternative line of reasoning involving combinations. Rather than focusing on selecting just the first five songs, think of playing all 100 songs in random order. The number of ways of choosing 10 of these songs to be the Bs (without regard to the order in which they are then played) is A 100 10 B . Now if we choose 9 of the 95 last 95 songs to be Bs, which can be done in A 9 B ways, that leaves four NBs and one B for the first five songs. There is only one further way for these five to start with Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 70 CHAPTER 2 Probability four NBs and then follow with a B (remember that we are considering unordered subsets). Thus P(1st B is the 5th song played) 5 a a 95 b 9 100 b 10 It is easily verified that this latter expression is in fact identical to the first expression for the desired probability, so the numerical result is again .0679. The probability that one of the first five songs played is a Beatles’ song is P(1st B is the 1st or 2nd or 3rd or 4th or 5th song played) 5 a 99 b 9 100 b a 10 1 a 98 b 9 100 b a 10 1 a 97 b 9 100 b a 10 1 a 96 b 9 100 b a 10 1 a 95 b 9 100 b a 10 5 .4162 It is thus rather likely that a Beatles’ song will be one of the first five songs played. Such a “coincidence” is not as surprising as might first appear to be the case. ■ Example 2.23 A university warehouse has received a shipment of 25 printers, of which 10 are laser printers and 15 are inkjet models. If 6 of these 25 are selected at random to be checked by a particular technician, what is the probability that exactly 3 of those selected are laser printers (so that the other 3 are inkjets)? Let D3 5 5exactly 3 of the 6 selected are inkjet printers6 . Assuming that any particular set of 6 printers is as likely to be chosen as is any other set of 6, we have equally likely outcomes, so P(D3) 5 N(D3)/N, where N is the number of ways of choosing 6 printers from the 25 and N(D3) is the number of ways of choosing 3 laser printers and 3 inkjet models. Thus N 5 A 256 B . To obtain N(D3), think of first choosing 3 of the 15 inkjet models and then 3 of the laser printers. There are A 153 B ways of choosing the 3 inkjet models, and there are A 103 B ways of choosing the 3 laser printers; N(D3) is now the product of these two numbers (visualize a tree diagram—we are really using a product rule argument here), so N(D3) P(D3) 5 5 N a 15 10 ba b 3 3 a 25 b 6 15! # 10! 3!12! 3!7! 5 5 .3083 25! 6!19! Let D4 5 5exactly 4 of the 6 printers selected are inkjet models6 and define D5 and D6 in an analogous manner. Then the probability that at least 3 inkjet printers are selected is P(D3 ´ D4 ´ D5 ´ D6) 5 P(D3) 1 P(D4) 1 P(D5) 1 P(D6) 5 a 15 10 ba b 3 3 a 25 b 6 1 a 15 10 ba b 4 2 a 25 b 6 1 a 15 10 ba b 5 1 a 25 b 6 1 a 15 10 ba b 6 0 a 25 b 6 5 .8530 ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.3 Counting Techniques EXERCISES 71 Section 2.3 (29–44) 29. As of April 2006, roughly 50 million .com web domain names were registered (e.g., yahoo.com). a. How many domain names consisting of just two letters in sequence can be formed? How many domain names of length two are there if digits as well as letters are permitted as characters? [Note: A character length of three or more is now mandated.] b. How many domain names are there consisting of three letters in sequence? How many of this length are there if either letters or digits are permitted? [Note: All are currently taken.] c. Answer the questions posed in (b) for four-character sequences. d. As of April 2006, 97,786 of the four-character sequences using either letters or digits had not yet been claimed. If a four-character name is randomly selected, what is the probability that it is already owned? 30. A friend of mine is giving a dinner party. His current wine supply includes 8 bottles of zinfandel, 10 of merlot, and 12 of cabernet (he only drinks red wine), all from different wineries. a. If he wants to serve 3 bottles of zinfandel and serving order is important, how many ways are there to do this? b. If 6 bottles of wine are to be randomly selected from the 30 for serving, how many ways are there to do this? c. If 6 bottles are randomly selected, how many ways are there to obtain two bottles of each variety? d. If 6 bottles are randomly selected, what is the probability that this results in two bottles of each variety being chosen? e. If 6 bottles are randomly selected, what is the probability that all of them are the same variety? 31. a. Beethoven wrote 9 symphonies, and Mozart wrote 27 piano concertos. If a university radio station announcer wishes to play first a Beethoven symphony and then a Mozart concerto, in how many ways can this be done? b. The station manager decides that on each successive night (7 days per week), a Beethoven symphony will be played, followed by a Mozart piano concerto, followed by a Schubert string quartet (of which there are 15). For roughly how many years could this policy be continued before exactly the same program would have to be repeated? 32. A stereo store is offering a special price on a complete set of components (receiver, compact disc player, speakers, turntable). A purchaser is offered a choice of manufacturer for each component: Receiver: Kenwood, Onkyo, Pioneer, Sony, Sherwood Compact disc player: Onkyo, Pioneer, Sony, Technics Speakers: Boston, Infinity, Polk Turntable: Onkyo, Sony, Teac, Technics A switchboard display in the store allows a customer to hook together any selection of components (consisting of one of each type). Use the product rules to answer the following questions: a. In how many ways can one component of each type be selected? b. In how many ways can components be selected if both the receiver and the compact disc player are to be Sony? c. In how many ways can components be selected if none is to be Sony? d. In how many ways can a selection be made if at least one Sony component is to be included? e. If someone flips switches on the selection in a completely random fashion, what is the probability that the system selected contains at least one Sony component? Exactly one Sony component? 33. Again consider a Little League team that has 15 players on its roster. a. How many ways are there to select 9 players for the starting lineup? b. How many ways are there to select 9 players for the starting lineup and a batting order for the 9 starters? c. Suppose 5 of the 15 players are left-handed. How many ways are there to select 3 left-handed outfielders and have all 6 other positions occupied by right-handed players? 34. Computer keyboard failures can be attributed to electrical defects or mechanical defects. A repair facility currently has 25 failed keyboards, 6 of which have electrical defects and 19 of which have mechanical defects. a. How many ways are there to randomly select 5 of these keyboards for a thorough inspection (without regard to order)? b. In how many ways can a sample of 5 keyboards be selected so that exactly two have an electrical defect? c. If a sample of 5 keyboards is randomly selected, what is the probability that at least 4 of these will have a mechanical defect? 35. A production facility employs 20 workers on the day shift, 15 workers on the swing shift, and 10 workers on the graveyard shift. A quality control consultant is to select 6 of these workers for in-depth interviews. Suppose the selection is made in such a way that any particular group of 6 workers has the same chance of being selected as does any other group (drawing 6 slips without replacement from among 45). a. How many selections result in all 6 workers coming from the day shift? What is the probability that all 6 selected workers will be from the day shift? b. What is the probability that all 6 selected workers will be from the same shift? c. What is the probability that at least two different shifts will be represented among the selected workers? d. What is the probability that at least one of the shifts will be unrepresented in the sample of workers? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 72 CHAPTER 2 Probability 36. An academic department with five faculty members narrowed its choice for department head to either candidate A or candidate B. Each member then voted on a slip of paper for one of the candidates. Suppose there are actually three votes for A and two for B. If the slips are selected for tallying in random order, what is the probability that A remains ahead of B throughout the vote count (e.g., this event occurs if the selected ordering is AABAB, but not for ABBAA)? 37. An experimenter is studying the effects of temperature, pressure, and type of catalyst on yield from a certain chemical reaction. Three different temperatures, four different pressures, and five different catalysts are under consideration. a. If any particular experimental run involves the use of a single temperature, pressure, and catalyst, how many experimental runs are possible? b. How many experimental runs are there that involve use of the lowest temperature and two lowest pressures? c. Suppose that five different experimental runs are to be made on the first day of experimentation. If the five are randomly selected from among all the possibilities, so that any group of five has the same probability of selection, what is the probability that a different catalyst is used on each run? 38. A box in a certain supply room contains four 40-W lightbulbs, five 60-W bulbs, and six 75-W bulbs. Suppose that three bulbs are randomly selected. a. What is the probability that exactly two of the selected bulbs are rated 75-W? b. What is the probability that all three of the selected bulbs have the same rating? c. What is the probability that one bulb of each type is selected? d. Suppose now that bulbs are to be selected one by one until a 75-W bulb is found. What is the probability that it is necessary to examine at least six bulbs? 39. Fifteen telephones have just been received at an authorized service center. Five of these telephones are cellular, five are cordless, and the other five are corded phones. Suppose that these components are randomly allocated the numbers 1, 2, . . . , 15 to establish the order in which they will be serviced. a. What is the probability that all the cordless phones are among the first ten to be serviced? b. What is the probability that after servicing ten of these phones, phones of only two of the three types remain to be serviced? c. What is the probability that two phones of each type are among the first six serviced? 40. Three molecules of type A, three of type B, three of type C, and three of type D are to be linked together to form a chain molecule. One such chain molecule is ABCDABCDABCD, and another is BCDDAAABDBCC. a. How many such chain molecules are there? [Hint: If the three A’s were distinguishable from one another—A1, A2, A3—and the B’s, C’s, and D’s were also, how many molecules would there be? How is this number reduced when the subscripts are removed from the A’s?] b. Suppose a chain molecule of the type described is randomly selected. What is the probability that all three molecules of each type end up next to one another (such as in BBBAAADDDCCC)? 41. An ATM personal identification number (PIN) consists of four digits, each a 0, 1, 2, . . . 8, or 9, in succession. a. How many different possible PINs are there if there are no restrictions on the choice of digits? b. According to a representative at the author’s local branch of Chase Bank, there are in fact restrictions on the choice of digits. The following choices are prohibited: (i) all four digits identical (ii) sequences of consecutive ascending or descending digits, such as 6543 (iii) any sequence starting with 19 (birth years are too easy to guess). So if one of the PINs in (a) is randomly selected, what is the probability that it will be a legitimate PIN (that is, not be one of the prohibited sequences)? c. Someone has stolen an ATM card and knows that the first and last digits of the PIN are 8 and 1, respectively. He has three tries before the card is retained by the ATM (but does not realize that). So he randomly selects the 2nd and 3rd digits for the first try, then randomly selects a different pair of digits for the second try, and yet another randomly selected pair of digits for the third try (the individual knows about the restrictions described in (b) so selects only from the legitimate possibilities). What is the probability that the individual gains access to the account? d. Recalculate the probability in (c) if the first and last digits are 1 and 1, respectively. 42. A starting lineup in basketball consists of two guards, two forwards, and a center. a. A certain college team has on its roster three centers, four guards, four forwards, and one individual (X) who can play either guard or forward. How many different starting lineups can be created? [Hint: Consider lineups without X, then lineups with X as guard, then lineups with X as forward.] b. Now suppose the roster has 5 guards, 5 forwards, 3 centers, and 2 “swing players” (X and Y) who can play either guard or forward. If 5 of the 15 players are randomly selected, what is the probability that they constitute a legitimate starting lineup? 43. In five-card poker, a straight consists of five cards with adjacent denominations (e.g., 9 of clubs, 10 of hearts, jack of hearts, queen of spades, and king of clubs). Assuming that aces can be high or low, if you are dealt a five-card hand, what is the probability that it will be a straight with high card 10? What is the probability that it will be a straight? What is the probability that it will be a straight flush (all cards in the same suit)? 44. Show that A nk B 5 A n subsets. n 2 k B . Give an interpretation involving Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.4 Conditional Probability 73 2.4 Conditional Probability The probabilities assigned to various events depend on what is known about the experimental situation when the assignment is made. Subsequent to the initial assignment, partial information relevant to the outcome of the experiment may become available. Such information may cause us to revise some of our probability assignments. For a particular event A, we have used P(A) to represent the probability, assigned to A; we now think of P(A) as the original, or unconditional probability, of the event A. In this section, we examine how the information “an event B has occurred” affects the probability assigned to A. For example, A might refer to an individual having a particular disease in the presence of certain symptoms. If a blood test is performed on the individual and the result is negative (B 5 negative blood test), then the probability of having the disease will change (it should decrease, but not usually to zero, since blood tests are not infallible). We will use the notation P(Au B) to represent the conditional probability of A given that the event B has occurred. B is the “conditioning event.” As an example, consider the event A that a randomly selected student at your university obtained all desired classes during the previous term’s registration cycle. Presumably P(A) is not very large. However, suppose the selected student is an athlete who gets special registration priority (the event B). Then P(A | B) should be substantially larger than P(A), although perhaps still not close to 1. Example 2.24 Complex components are assembled in a plant that uses two different assembly lines, A and A⬘. Line A uses older equipment than A⬘, so it is somewhat slower and less reliable. Suppose on a given day line A has assembled 8 components, of which 2 have been identified as defective (B) and 6 as nondefective (B⬘), whereas A⬘ has produced 1 defective and 9 nondefective components. This information is summarized in the accompanying table. Condition Line A A⬘ B B⬘ 2 1 6 9 Unaware of this information, the sales manager randomly selects 1 of these 18 components for a demonstration. Prior to the demonstration P(line A component selected) 5 P(A) 5 8 N(A) 5 5 .44 N 18 However, if the chosen component turns out to be defective, then the event B has occurred, so the component must have been 1 of the 3 in the B column of the table. Since these 3 components are equally likely among themselves after B has occurred, P(Au B) 5 2 2/18 P(A ¨ B) 5 5 3 3/18 P(B) (2.2) ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 74 CHAPTER 2 Probability In Equation (2.2), the conditional probability is expressed as a ratio of unconditional probabilities: The numerator is the probability of the intersection of the two events, whereas the denominator is the probability of the conditioning event B. A Venn diagram illuminates this relationship (Figure 2.8). A B Figure 2.8 Motivating the definition of conditional probability Given that B has occurred, the relevant sample space is no longer S but consists of outcomes in B; A has occurred if and only if one of the outcomes in the intersection occurred, so the conditional probability of A given B is proportional to P(A ¨ B). The proportionality constant 1/P(B) is used to ensure that the probability P(Bu B) of the new sample space B equals 1. The Definition of Conditional Probability Example 2.24 demonstrates that when outcomes are equally likely, computation of conditional probabilities can be based on intuition. When experiments are more complicated, though, intuition may fail us, so a general definition of conditional probability is needed that will yield intuitive answers in simple problems. The Venn diagram and Equation (2.2) suggest how to proceed. DEFINITION For any two events A and B with P(B) . 0, the conditional probability of A given that B has occurred is defined by P(Au B) 5 Example 2.25 P(A ¨ B) P(B) (2.3) Suppose that of all individuals buying a certain digital camera, 60% include an optional memory card in their purchase, 40% include an extra battery, and 30% include both a card and battery. Consider randomly selecting a buyer and let A 5 5memory card purchased6 and B 5 5battery purchased6 . Then P(A) 5 .60, P(B) 5 .40, and P(both purchased) 5 P(A ¨ B) 5 .30. Given that the selected individual purchased an extra battery, the probability that an optional card was also purchased is P(Au B) 5 P(A ¨ B) .30 5 5 .75 P(B) .40 That is, of all those purchasing an extra battery, 75% purchased an optional memory card. Similarly, P(battery u memory card) 5 P(B u A) 5 Notice that P(Au B) 2 P(A) and P(Bu A) 2 P(B). P(A ¨ B) .30 5 5 .50 P(A) .60 ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.4 Conditional Probability 75 The event whose probability is desired might be a union or intersection of other events, and the same could be true of the conditioning event. Example 2.26 A news magazine publishes three columns entitled “Art” (A), “Books” (B), and “Cinema” (C). Reading habits of a randomly selected reader with respect to these columns are Read regularly Probability A .14 B .23 C .37 A¨B .08 A¨C .09 B¨C .13 A¨B¨C .05 Figure 2.9 illustrates relevant probabilities. A B .02 .03 .07 .05 .04 .08 .20 .51 Figure 2.9 C Venn diagram for Example 2.26 We thus have P(A ¨ B) .08 5 5 .348 P(B) .23 P(A ¨ (B ´ C)) .04 1 .05 1 .03 .12 P(Au B ´ C) 5 5 5 5 .255 P(B ´ C) .47 .47 P(A ¨ (A ´ B ´ C)) P(A u reads at least one) 5 P(Au A ´ B ´ C) 5 P(A ´ B ´ C) P(A) .14 5 5 5 .286 P(A ´ B ´ C) .49 P(Au B) 5 and P(A ´ Bu C) 5 P((A ´ B) ¨ C) .04 1 .05 1 .08 5 5 .459 P(C) .37 ■ The Multiplication Rule for P (A ¨ B ) The definition of conditional probability yields the following result, obtained by multiplying both sides of Equation (2.3) by P(B). The Multiplication Rule P(A ¨ B) 5 P(Au B) # P(B) This rule is important because it is often the case that P(A ¨ B) is desired, whereas both P(B) and P(Au B) can be specified from the problem description. Consideration of P(Bu A) gives P(A ¨ B) 5 P(Bu A) # P(A). Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 76 CHAPTER 2 Probability Example 2.27 Four individuals have responded to a request by a blood bank for blood donations. None of them has donated before, so their blood types are unknown. Suppose only type O⫹ is desired and only one of the four actually has this type. If the potential donors are selected in random order for typing, what is the probability that at least three individuals must be typed to obtain the desired type? Making the identification B 5 5first type not O16 and A 5 5second type not O16 , P(B) 5 34. Given that the first type is not O⫹, two of the three individuals left are not O⫹, so P(Au B) 5 23. The multiplication rule now gives P(at least three individuals are typed) 5 P(A ¨ B) 5 P(Au B) # P(B) 6 2 3 5 ? 5 3 4 12 5 .5 ■ The multiplication rule is most useful when the experiment consists of several stages in succession. The conditioning event B then describes the outcome of the first stage and A the outcome of the second, so that P(Au B)—conditioning on what occurs first—will often be known. The rule is easily extended to experiments involving more than two stages. For example, P(A1 ¨ A2 ¨ A3) 5 P(A3 u A1 ¨ A2) # P(A1 ¨ A2) 5 P(A3 u A1 ¨ A2) # P(A2 u A1) # P(A1) (2.4) where A1 occurs first, followed by A2, and finally A3. Example 2.28 For the blood typing experiment of Example 2.27, P(third type is O1) 5 P(third isu first isn’t ¨ second isn’t) # P(second isn’tu first isn’t) # P(first isn’t) 1 2 3 1 5 # # 5 5 .25 2 3 4 4 ■ When the experiment of interest consists of a sequence of several stages, it is convenient to represent these with a tree diagram. Once we have an appropriate tree diagram, probabilities and conditional probabilities can be entered on the various branches; this will make repeated use of the multiplication rule quite straightforward. Example 2.29 A chain of video stores sells three different brands of DVD players. Of its DVD player sales, 50% are brand 1 (the least expensive), 30% are brand 2, and 20% are brand 3. Each manufacturer offers a 1-year warranty on parts and labor. It is known that 25% of brand 1’s DVD players require warranty repair work, whereas the corresponding percentages for brands 2 and 3 are 20% and 10%, respectively. 1. What is the probability that a randomly selected purchaser has bought a brand 1 DVD player that will need repair while under warranty? 2. What is the probability that a randomly selected purchaser has a DVD player that will need repair while under warranty? 3. If a customer returns to the store with a DVD player that needs warranty repair work, what is the probability that it is a brand 1 DVD player? A brand 2 DVD player? A brand 3 DVD player? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.4 Conditional Probability 77 The first stage of the problem involves a customer selecting one of the three brands of DVD player. Let Ai 5 5brand i is purchased6 , for i 5 1, 2, and 3. Then P(A1) 5 .50, P(A2) 5 .30, and P(A3) 5 .20. Once a brand of DVD player is selected, the second stage involves observing whether the selected DVD player needs warranty repair. With B 5 5needs repair6 and Br 5 5doesn’t need repair6 , the given information implies that P(Bu A1) 5 .25, P(Bu A2) 5 .20, and P(Bu A3) 5 .10. The tree diagram representing this experimental situation is shown in Figure 2.10. The initial branches correspond to different brands of DVD players; there are two second-generation branches emanating from the tip of each initial branch, one for “needs repair” and the other for “doesn’t need repair.” The probability P(Ai) appears on the ith initial branch, whereas the conditional probabilities P(Bu Ai) and P(Br u Ai) appear on the second-generation branches. To the right of each second-generation branch corresponding to the occurrence of B, we display the product of probabilities on the branches leading out to that point. This is simply the multiplication rule in action. The answer to the question posed in 1 is thus P(A1 ¨ B) 5 P(Bu A1) # P(A1) 5 .125. The answer to question 2 is P(B) 5 P[(brand 1 and repair) or (brand 2 and repair) or (brand 3 and repair)] 5 P(A1 ¨ B) 1 P(A2 ¨ B) 1 P(A3 ¨ B) 5 .125 1 .060 1 .020 5 .205 .25 A 1) P(B ir Repa P(B' A P( ) 1 No re pair d1 an P(A2) .30 P(B 3) an d3 P(B A2) P(A2) P(B A2) .060 .20 A) 2 . 80 No re pair A Br A 2) ir Repa P(B' Brand 2 P( A) 1 . 75 .50 Br P(B A1) P(A1) P(B A1) .125 .20 .10 A 3) P(B ir Repa P(B' P(B A3) P(A3) P(B A3) .020 A) 3 . 90 No re pair P(B) .205 Figure 2.10 Tree diagram for Example 2.29 Finally, P(A1 ¨ B) .125 5 5 .61 P(B) .205 P(A2 ¨ B) .060 P(A2 u B) 5 5 5 .29 P(B) .205 P(A1 u B) 5 and P(A3 u B) 5 1 2 P(A1 u B) 2 P(A2 u B) 5 .10 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 78 CHAPTER 2 Probability The initial or prior probability of brand 1 is .50. Once it is known that the selected DVD player needed repair, the posterior probability of brand 1 increases to .61. This is because brand 1 DVD players are more likely to need warranty repair than are the other brands. The posterior probability of brand 3 is P(A3 u B) 5 .10, which is much less than the prior probability P(A3) 5 .20. ■ Bayes’ Theorem The computation of a posterior probability P(Aj u B) from given prior probabilities P(Ai) and conditional probabilities P(Bu Ai) occupies a central position in elementary probability. The general rule for such computations, which is really just a simple application of the multiplication rule, goes back to Reverend Thomas Bayes, who lived in the eighteenth century. To state it we first need another result. Recall that events A1, . . . , Ak are mutually exclusive if no two have any common outcomes. The events are exhaustive if one Ai must occur, so that A1 ´ c ´ Ak 5 S . The Law of Total Probability Let A1, . . . , Ak be mutually exclusive and exhaustive events. Then for any other event B, P(B) 5 P(Bu A1)P(A1) 1 c 1 P(Bu Ak)P(Ak) k 5 g P(Bu Ai)P(Ai) (2.5) i51 Proof Because the Ai’s are mutually exclusive and exhaustive, if B occurs it must be in conjunction with exactly one of the Ai’s. That is, B 5 (A1 ¨ B) ´ c ´ (Ak ¨ B), where the events (Ai ¨ B) are mutually exclusive. This “partitioning of B” is illustrated in Figure 2.11. Thus P(B) 5 k k i51 i51 g P(Ai ¨ B) 5 g P(Bu Ai)P(Ai) is desired. B A1 A2 Figure 2.11 Example 2.30 A3 A4 Partition of B by mutually exclusive and exhaustive Ai’s ■ An individual has 3 different email accounts. Most of her messages, in fact 70%, come into account #1, whereas 20% come into account #2 and the remaining 10% into account #3. Of the messages into account #1, only 1% are spam, whereas the corresponding percentages for accounts #2 and #3 are 2% and 5%, respectively. What is the probability that a randomly selected message is spam? To answer this question, let’s first establish some notation: Ai 5 5message is from account [ i6 for i 5 1, 2, 3, B 5 5message is spam6 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.4 Conditional Probability 79 Then the given percentages imply that P(A1) 5 .70, P(A2) 5 .20, P(A3) 5 .10 P(Bu A1) 5 .01, P(Bu A2) 5 .02, P(Bu A3) 5 .05 Now it is simply a matter of substituting into the equation for the law of total probability: P(B) 5 (.01)(.70) 1 (.02)(.20) 1 (.05)(.10) 5 .016 ■ In the long run, 1.6% of this individual’s messages will be spam. Bayes’ Theorem Let A1, A2, . . . , Ak be a collection of k mutually exclusive and exhaustive events with prior probabilities P(Ai) (i 5 1, c, k). Then for any other event B for which P(B) . 0, the posterior probability of Aj given that B has occurred is P(Aj u B) 5 P(Aj ¨ B) P(B) 5 P(Bu Aj)P(Aj) k g P(Bu Ai) # P(Ai) j 5 1, c, k (2.6) i51 The transition from the second to the third expression in (2.6) rests on using the multiplication rule in the numerator and the law of total probability in the denominator. The proliferation of events and subscripts in (2.6) can be a bit intimidating to probability newcomers. As long as there are relatively few events in the partition, a tree diagram (as in Example 2.29) can be used as a basis for calculating posterior probabilities without ever referring explicitly to Bayes’ theorem. Example 2.31 Incidence of a rare disease. Only 1 in 1000 adults is afflicted with a rare disease for which a diagnostic test has been developed. The test is such that when an individual actually has the disease, a positive result will occur 99% of the time, whereas an individual without the disease will show a positive test result only 2% of the time. If a randomly selected individual is tested and the result is positive, what is the probability that the individual has the disease? To use Bayes’ theorem, let A1 5 individual has the disease, A2 5 individual does not have the disease, and B 5 positive test result. Then P(A1) 5 .001, P(A2) 5 .999, P(Bu A1) 5 .99, and P(Bu A2) 5 .02. The tree diagram for this problem is in Figure 2.12. P(A1 B) .00099 .99 st .001 A1 as H Te B .01 ase dise .999 A2 Doe sn't hav ed B' Tes t P(A2 B) .01998 .02 st isea se Te B .98 B' Figure 2.12 Tes t Tree diagram for the rare-disease problem Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 80 CHAPTER 2 Probability Next to each branch corresponding to a positive test result, the multiplication rule yields the recorded probabilities. Therefore, P(B) 5 .00099 1 .01998 5 .02097, from which we have P(A1 u B) 5 P(A1 ¨ B) .00099 5 5 .047 P(B) .02097 This result seems counterintuitive; the diagnostic test appears so accurate that we expect someone with a positive test result to be highly likely to have the disease, whereas the computed conditional probability is only .047. However, the rarity of the disease implies that most positive test results arise from errors rather than from diseased individuals. The probability of having the disease has increased by a multiplicative factor of 47 (from prior .001 to posterior .047); but to get a further increase in the posterior probability, a diagnostic test with much smaller error rates is needed. ■ EXERCISES Section 2.4 (45–69) 45. The population of a particular country consists of three ethnic groups. Each individual belongs to one of the four major blood groups. The accompanying joint probability table gives the proportions of individuals in the various ethnic group–blood group combinations. Blood Group Ethnic Group 1 2 3 O A B AB .082 .135 .215 .106 .141 .200 .008 .018 .065 .004 .006 .020 Suppose that an individual is randomly selected from the population, and define events by A 5 5type A selected6 , B 5 5type B selected6 , and C 5 5ethnic group 3 selected6 . a. Calculate P(A), P(C), and P(A ¨ C). b. Calculate both P(A u C) and P(Cu A), and explain in context what each of these probabilities represents. c. If the selected individual does not have type B blood, what is the probability that he or she is from ethnic group 1? 46. Suppose an individual is randomly selected from the population of all adult males living in the United States. Let A be the event that the selected individual is over 6 ft in height, and let B be the event that the selected individual is a professional basketball player. Which do you think is larger, P(Au B) or P(Bu A)? Why? 47. Return to the credit card scenario of Exercise 12 (Section 2.2), where A 5 5Visa6 , B 5 5MasterCard6 , P(A) 5 .5, P(B) 5 .4, and P(A ¨ B) 5 .25. Calculate and interpret each of the following probabilities (a Venn diagram might help). a. P(B u A) b. P(Br u A) c. P(A u B) d. P(Ar u B) e. Given that the selected individual has at least one card, what is the probability that he or she has a Visa card? 48. Reconsider the system defect situation described in Exercise 26 (Section 2.2). a. Given that the system has a type 1 defect, what is the probability that it has a type 2 defect? b. Given that the system has a type 1 defect, what is the probability that it has all three types of defects? c. Given that the system has at least one type of defect, what is the probability that it has exactly one type of defect? d. Given that the system has both of the first two types of defects, what is the probability that it does not have the third type of defect? 49. The accompanying table gives information on the type of coffee selected by someone purchasing a single cup at a particular airport kiosk. Regular Decaf Small Medium Large 14% 20% 20% 10% 26% 10% Consider randomly selecting such a coffee purchaser. a. What is the probability that the individual purchased a small cup? A cup of decaf coffee? b. If we learn that the selected individual purchased a small cup, what now is the probability that he/she chose decaf coffee, and how would you interpret this probability? c. If we learn that the selected individual purchased decaf, what now is the probability that a small size was selected, and how does this compare to the corresponding unconditional probability of (a)? 50. A department store sells sport shirts in three sizes (small, medium, and large), three patterns (plaid, print, and stripe), and two sleeve lengths (long and short). The accompanying tables give the proportions of shirts sold in the various category combinations. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.4 Conditional Probability Short-sleeved Pattern Size Pl Pr St S M L .04 .08 .03 .02 .07 .07 .05 .12 .08 Long-sleeved Pattern Size Pl Pr St S M L .03 .10 .04 .02 .05 .02 .03 .07 .08 81 53. A certain shop repairs both audio and video components. Let A denote the event that the next component brought in for repair is an audio component, and let B be the event that the next component is a compact disc player (so the event B is contained in A). Suppose that P(A) 5 .6 and P(B) 5 .05. What is P(Bu A)? 54. In Exercise 13, Ai 5 5awarded project i6 , for i 5 1, 2, 3. Use the probabilities given there to compute the following probabilities, and explain in words the meaning of each one. a. P(A2 u A1) b. P(A2 ¨ A3 u A1) c. P(A2 ´ A3 u A1) d. P(A1 ¨ A2 ¨ A3 u A1 ´ A2 ´ A3). 55. Deer ticks can be carriers of either Lyme disease or human granulocytic ehrlichiosis (HGE). Based on a recent study, suppose that 16% of all ticks in a certain location carry Lyme disease, 10% carry HGE, and 10% of the ticks that carry at least one of these diseases in fact carry both of them. If a randomly selected tick is found to have carried HGE, what is the probability that the selected tick is also a carrier of Lyme disease? 56. For any events A and B with P(B) . 0, show that P(Au B) 1 P(Ar u B) 5 1. a. What is the probability that the next shirt sold is a medium, long-sleeved, print shirt? b. What is the probability that the next shirt sold is a medium print shirt? c. What is the probability that the next shirt sold is a shortsleeved shirt? A long-sleeved shirt? d. What is the probability that the size of the next shirt sold is medium? That the pattern of the next shirt sold is a print? e. Given that the shirt just sold was a short-sleeved plaid, what is the probability that its size was medium? f. Given that the shirt just sold was a medium plaid, what is the probability that it was short-sleeved? Longsleeved? 51. One box contains six red balls and four green balls, and a second box contains seven red balls and three green balls. A ball is randomly chosen from the first box and placed in the second box. Then a ball is randomly selected from the second box and placed in the first box. a. What is the probability that a red ball is selected from the first box and a red ball is selected from the second box? b. At the conclusion of the selection process, what is the probability that the numbers of red and green balls in the first box are identical to the numbers at the beginning? 52. A system consists of two identical pumps, #1 and #2. If one pump fails, the system will still operate. However, because of the added strain, the remaining pump is now more likely to fail than was originally the case. That is, r 5 P(#2 fails ⏐ #1 fails) ⬎ P(#2 fails) 5 q. If at least one pump fails by the end of the pump design life in 7% of all systems and both pumps fail during that period in only 1%, what is the probability that pump #1 will fail during the pump design life? 57. If P(Bu A) . P(B), show that P(Br u A) , P(Br). [Hint: Add P(Br u A) to both sides of the given inequality and then use the result of Exercise 56.] 58. Show that for any three events A, B, and C with P(C) . 0, P(A ´ Bu C) 5 P(Au C) 1 P(Bu C) 2 P(A ¨ Bu C). 59. At a certain gas station, 40% of the customers use regular gas (A1), 35% use plus gas (A2), and 25% use premium (A3). Of those customers using regular gas, only 30% fill their tanks (event B). Of those customers using plus, 60% fill their tanks, whereas of those using premium, 50% fill their tanks. a. What is the probability that the next customer will request plus gas and fill the tank (A2 ¨ B)? b. What is the probability that the next customer fills the tank? c. If the next customer fills the tank, what is the probability that regular gas is requested? Plus? Premium? 60. Seventy percent of the light aircraft that disappear while in flight in a certain country are subsequently discovered. Of the aircraft that are discovered, 60% have an emergency locator, whereas 90% of the aircraft not discovered do not have such a locator. Suppose a light aircraft has disappeared. a. If it has an emergency locator, what is the probability that it will not be discovered? b. If it does not have an emergency locator, what is the probability that it will be discovered? 61. Components of a certain type are shipped to a supplier in batches of ten. Suppose that 50% of all such batches contain no defective components, 30% contain one defective component, and 20% contain two defective components. Two components from a batch are randomly selected and tested. What Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 82 CHAPTER 2 Probability are the probabilities associated with 0, 1, and 2 defective components being in the batch under each of the following conditions? a. Neither tested component is defective. b. One of the two tested components is defective. [Hint: Draw a tree diagram with three first-generation branches for the three different types of batches.] 62. A company that manufactures video cameras produces a basic model and a deluxe model. Over the past year, 40% of the cameras sold have been of the basic model. Of those buying the basic model, 30% purchase an extended warranty, whereas 50% of all deluxe purchasers do so. If you learn that a randomly selected purchaser has an extended warranty, how likely is it that he or she has a basic model? 63. For customers purchasing a refrigerator at a certain appliance store, let A be the event that the refrigerator was manufactured in the U.S., B be the event that the refrigerator had an icemaker, and C be the event that the customer purchased an extended warranty. Relevant probabilities are P(A) 5 .75 P(B u A) 5 .9 P(B u Ar) 5 .8 P(C u A ¨ B) 5 .8 P(Cu A ¨ Br) 5 .6 P(C u Ar ¨ B) 5 .7 P(C u Ar ¨ Br) 5 .3 a. Construct a tree diagram consisting of first-, second-, and third-generation branches, and place an event label and appropriate probability next to each branch. b. Compute P(A ¨ B ¨ C). c. Compute P(B ¨ C). d. Compute P(C). e. Compute P(Au B ¨ C), the probability of a U.S. purchase given that an icemaker and extended warranty are also purchased. 64. The Reviews editor for a certain scientific journal decides whether the review for any particular book should be short (1–2 pages), medium (3–4 pages), or long (5–6 pages). Data on recent reviews indicates that 60% of them are short, 30% are medium, and the other 10% are long. Reviews are submitted in either Word or LaTeX. For short reviews, 80% are in Word, whereas 50% of medium reviews are in Word and 30% of long reviews are in Word. Suppose a recent review is randomly selected. a. What is the probability that the selected review was submitted in Word format? b. If the selected review was submitted in Word format, what are the posterior probabilities of it being short, medium, or long? 65. A large operator of timeshare complexes requires anyone interested in making a purchase to first visit the site of interest. Historical data indicates that 20% of all potential purchasers select a day visit, 50% choose a one-night visit, and 30% opt for a two-night visit. In addition, 10% of day visitors ultimately make a purchase, 30% of onenight visitors buy a unit, and 20% of those visiting for two nights decide to buy. Suppose a visitor is randomly selected and is found to have made a purchase. How likely is it that this person made a day visit? A one-night visit? A two-night visit? 66. Consider the following information about travelers on vacation (based partly on a recent Travelocity poll): 40% check work email, 30% use a cell phone to stay connected to work, 25% bring a laptop with them, 23% both check work email and use a cell phone to stay connected, and 51% neither check work email nor use a cell phone to stay connected nor bring a laptop. In addition, 88 out of every 100 who bring a laptop also check work email, and 70 out of every 100 who use a cell phone to stay connected also bring a laptop. a. What is the probability that a randomly selected traveler who checks work email also uses a cell phone to stay connected? b. What is the probability that someone who brings a laptop on vacation also uses a cell phone to stay connected? c. If the randomly selected traveler checked work email and brought a laptop, what is the probability that he/she uses a cell phone to stay connected? 67. There has been a great deal of controversy over the last several years regarding what types of surveillance are appropriate to prevent terrorism. Suppose a particular surveillance system has a 99% chance of correctly identifying a future terrorist and a 99.9% chance of correctly identifying someone who is not a future terrorist. If there are 1000 future terrorists in a population of 300 million, and one of these 300 million is randomly selected, scrutinized by the system, and identified as a future terrorist, what is the probability that he/she actually is a future terrorist? Does the value of this probability make you uneasy about using the surveillance system? Explain. 68. A friend who lives in Los Angeles makes frequent consulting trips to Washington, D.C.; 50% of the time she travels on airline #1, 30% of the time on airline #2, and the remaining 20% of the time on airline #3. For airline #1, flights are late into D.C. 30% of the time and late into L.A. 10% of the time. For airline #2, these percentages are 25% and 20%, whereas for airline #3 the percentages are 40% and 25%. If we learn that on a particular trip she arrived late at exactly one of the two destinations, what are the posterior probabilities of having flown on airlines #1, #2, and #3?Assume that the chance of a late arrival in L.A. is unaffected by what happens on the flight to D.C. [Hint: From the tip of each first-generation branch on a tree diagram, draw three second-generation branches labeled, respectively, 0 late, 1 late, and 2 late.] 69. In Exercise 59, consider the following additional information on credit card usage: 70% of all regular fill-up customers use a credit card. 50% of all regular non-fill-up customers use a credit card. 60% of all plus fill-up customers use a credit card. 50% of all plus non-fill-up customers use a credit card. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 83 2.5 Independence 50% of all premium fill-up customers use a credit card. 40% of all premium non-fill-up customers use a credit card. Compute the probability of each of the following events for the next customer to arrive (a tree diagram might help). a. {plus and fill-up and credit card} b. {premium and non-fill-up and credit card} c. d. e. f. {premium and credit card} {fill-up and credit card} {credit card} If the next customer uses a credit card, what is the probability that premium was requested? 2.5 Independence The definition of conditional probability enables us to revise the probability P(A) originally assigned to A when we are subsequently informed that another event B has occurred; the new probability of A is P(Au B). In our examples, it was frequently the case that P(Au B) differed from the unconditional probability P(A), indicating that the information “B has occurred” resulted in a change in the chance of A occurring. Often the chance that A will occur or has occurred is not affected by knowledge that B has occurred, so that P(Au B) 5 P(A). It is then natural to regard A and B as independent events, meaning that the occurrence or nonoccurrence of one event has no bearing on the chance that the other will occur. DEFINITION Two events A and B are independent if P(Au B) 5 P(A) and are dependent otherwise. The definition of independence might seem “unsymmetric” because we do not also demand that P(Bu A) 5 P(B). However, using the definition of conditional probability and the multiplication rule, P(Bu A) 5 P(A ¨ B) P(Au B)P(B) 5 P(A) P(A) (2.7) The right-hand side of Equation (2.7) is P(B) if and only if P(Au B) 5 P(A) (independence), so the equality in the definition implies the other equality (and vice versa). It is also straightforward to show that if A and B are independent, then so are the following pairs of events: (1) A⬘ and B, (2) A and B⬘, and (3) A⬘ and B⬘. Example 2.32 Consider a gas station with six pumps numbered 1, 2, . . . , 6, and let Ei denote the simple event that a randomly selected customer uses pump i (i 5 1, c, 6). Suppose that P(E1) 5 P(E6) 5 .10, P(E2) 5 P(E5) 5 .15, P(E3) 5 P(E4) 5 .25 Define events A, B, C by A 5 52, 4, 66 , B 5 51, 2, 36 , C 5 52, 3, 4, 56 . We then have P(A) 5 .50, P(Au B) 5 .30, and P(Au C) 5 .50. That is, events A and B are dependent, whereas events A and C are independent. Intuitively, A and C are independent because the relative division of probability among even- and odd-numbered pumps is the same among pumps 2, 3, 4, 5 as it is among all six pumps. ■ Example 2.33 Let A and B be any two mutually exclusive events with P(A) . 0. For example, for a randomly chosen automobile, let A 5 5the car has a four cylinder engine6 and B 5 5the car has a six cylinder engine6 . Since the events are mutually exclusive, if B occurs, then A cannot possibly have occurred, so P(Au B) 5 0 2 P(A). The message here is that if two events are mutually exclusive, they cannot be independent. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 84 CHAPTER 2 Probability When A and B are mutually exclusive, the information that A occurred says something about B (it cannot have occurred), so independence is precluded. ■ The Multiplication Rule for P(A " B ) Frequently the nature of an experiment suggests that two events A and B should be assumed independent. This is the case, for example, if a manufacturer receives a circuit board from each of two different suppliers, each board is tested on arrival, and A 5 5first is defective6 and B 5 5second is defective6 . If P(A) 5 .1, it should also be the case that P(Au B) 5 .1; knowing the condition of the second board shouldn’t provide information about the condition of the first. The probability that both events will occur is easily calculated from the individual event probabilities when the events are independent. PROPOSITION A and B are independent if and only if (iff) P(A ¨ B) 5 P(A) # P(B) (2.8) The verification of this multiplication rule is as follows: P(A ¨ B) 5 P(Au B) # P(B) 5 P(A) # P(B) (2.9) where the second equality in Equation (2.9) is valid iff A and B are independent. Equivalence of independence and Equation (2.8) imply that the latter can be used as a definition of independence. Example 2.34 It is known that 30% of a certain company’s washing machines require service while under warranty, whereas only 10% of its dryers need such service. If someone purchases both a washer and a dryer made by this company, what is the probability that both machines will need warranty service? Let A denote the event that the washer needs service while under warranty, and let B be defined analogously for the dryer. Then P(A) 5 .30 and P(B) 5 .10. Assuming that the two machines will function independently of one another, the desired probability is P(A ¨ B) 5 P(A) # P(B) 5 (.30)(.10) 5 .03 ■ It is straightforward to show that A and B are independent iff A⬘ and B are independent, A and B⬘ are independent, and A⬘and B⬘ are independent. Thus in Example 2.34, the probability that neither machine needs service is P(Ar ¨ Br) 5 P(Ar) # P(Br) 5 (.70)(.90) 5 .63 Example 2.35 Each day, Monday through Friday, a batch of components sent by a first supplier arrives at a certain inspection facility. Two days a week, a batch also arrives from a second supplier. Eighty percent of all supplier 1’s batches pass inspection, and 90% of supplier 2’s do likewise. What is the probability that, on a randomly selected day, two batches pass inspection? We will answer this assuming that on days when two batches are tested, whether the first batch passes is independent of whether the second batch does so. Figure 2.13 displays the relevant information. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.5 Independence 85 .8 es Pass .2 .6 .4 2 ba tche es pass 2nd .1 .8 s 2nd f asse 1st p .2 s .4 (.8 .9) .9 Fails tch 1 ba ails .9 asses 2nd p .1 1st fa ils 2nd Figure 2.13 fails Tree diagram for Example 2.35 P(two pass) 5 P(two received ¨ both pass) 5 P(both passu two received) # P(two received) 5 [(.8)(.9)](.4) 5 .288 ■ Independence of More Than Two Events The notion of independence of two events can be extended to collections of more than two events. Although it is possible to extend the definition for two independent events by working in terms of conditional and unconditional probabilities, it is more direct and less cumbersome to proceed along the lines of the last proposition. DEFINITION Events A1, . . . , An are mutually independent if for every k (k 5 2, 3, c, n) and every subset of indices i1, i2, . . . , ik, P(Ai1 ¨ Ai2 ¨ c ¨ Aik) 5 P(Ai1) # P(Ai2) # c # P(Aik) To paraphrase the definition, the events are mutually independent if the probability of the intersection of any subset of the n events is equal to the product of the individual probabilities. In using the multiplication property for more than two independent events, it is legitimate to replace one or more of the Ais by their complements (e.g., if A1, A2, and A3 are independent events, so are A1r, A2r, and A3r). As was the case with two events, we frequently specify at the outset of a problem the independence of certain events. The probability of an intersection can then be calculated via multiplication. Example 2.36 The article “Reliability Evaluation of Solar Photovoltaic Arrays”(Solar Energy, 2002: 129–141) presents various configurations of solar photovoltaic arrays consisting of crystalline silicon solar cells. Consider first the system illustrated in Figure 2.14(a). 1 2 3 1 2 3 4 5 6 4 5 6 (a) Figure 2.14 (b) System configurations for Example 2.36: (a) series-parallel; (b) total-cross-tied Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 86 CHAPTER 2 Probability There are two subsystems connected in parallel, each one containing three cells. In order for the system to function, at least one of the two parallel subsystems must work. Within each subsystem, the three cells are connected in series, so a subsystem will work only if all cells in the subsystem work. Consider a particular lifetime value t0, and supose we want to determine the probability that the system lifetime exceeds t0. Let Ai denote the event that the lifetime of cell i exceeds t0 (i 5 1, 2, c, 6). We assume that the Ars i are independent events (whether any particular cell lasts more than t0 hours has no bearing on whether or not any other cell does) and that P(Ai) 5 .9 for every i since the cells are identical. Then P(system lifetime exceeds t0) 5 P[(A1 ¨ A2 ¨ A3) ´ (A4 ¨ A5 ¨ A6)] 5 P(A1 ¨ A2 ¨ A3) 1 P(A4 ¨ A5 ¨ A6) 2 P[(A1 ¨ A2 ¨ A3) ¨ (A4 ¨ A5 ¨ A6)] 5 (.9)(.9)(.9) 1 (.9)(.9)(.9) 2 (.9)(.9)(.9)(.9)(.9)(.9) 5 .927 Alternatively, P(system lifetime exceeds t0) 5 5 5 5 1 1 1 1 2 2 2 2 P(both subsystem lives are # t0) [P(subsystem life is # t0)]2 [1 2 P(subsystem life is . t0)]2 [1 2 (.9)3]2 5 .927 Next consider the total-cross-tied system shown in Figure 2.14(b), obtained from the series-parallel array by connecting ties across each column of junctions. Now the system fails as soon as an entire column fails, and system lifetime exceeds t0 only if the life of every column does so. For this configuration, P(system lifetime is at least t0) 5 [P(column lifetime exceeds t0)]3 5 [1 2 P(column lifetime is # t0)]3 5 [1 2 P(both cells in a column have lifetime # t0)]3 5 [1 2 (1 2 .9)2]3 5 .970 ■ EXERCISES Section 2.5 (70–89) 70. Reconsider the credit card scenario of Exercise 47 (Section 2.4), and show that A and B are dependent first by using the definition of independence and then by verifying that the multiplication property does not hold. 71. An oil exploration company currently has two active projects, one in Asia and the other in Europe. Let A be the event that the Asian project is successful and B be the event that the European project is successful. Suppose that A and B are independent events with P(A) 5 .4 and P(B) 5 .7. a. If the Asian project is not successful, what is the probability that the European project is also not successful? Explain your reasoning. b. What is the probability that at least one of the two projects will be successful? c. Given that at least one of the two projects is successful, what is the probability that only the Asian project is successful? 72. In Exercise 13, is any Ai independent of any other Aj? Answer using the multiplication property for independent events. 73. If A and B are independent events, show that A⬘ and B are also independent. [Hint: First establish a relationship between P(Ar ¨ B), P(B), and P(A ¨ B).] 74. The proportions of blood phenotypes in the U.S. population are as follows: A .40 B .11 AB .04 O .45 Assuming that the phenotypes of two randomly selected individuals are independent of one another, what is the probability that both phenotypes are O? What is the probability that the phenotypes of two randomly selected individuals match? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 2.5 Independence 75. One of the assumptions underlying the theory of control charting (see Chapter 16) is that successive plotted points are independent of one another. Each plotted point can signal either that a manufacturing process is operating correctly or that there is some sort of malfunction. Even when a process is running correctly, there is a small probability that a particular point will signal a problem with the process. Suppose that this probability is .05. What is the probability that at least one of 10 successive points indicates a problem when in fact the process is operating correctly? Answer this question for 25 successive points. 76. In October, 1994, a flaw in a certain Pentium chip installed in computers was discovered that could result in a wrong answer when performing a division. The manufacturer initially claimed that the chance of any particular division being incorrect was only 1 in 9 billion, so that it would take thousands of years before a typical user encountered a mistake. However, statisticians are not typical users; some modern statistical techniques are so computationally intensive that a billion divisions over a short time period is not outside the realm of possibility. Assuming that the 1 in 9 billion figure is correct and that results of different divisions are independent of one another, what is the probability that at least one error occurs in one billion divisions with this chip? 77. An aircraft seam requires 25 rivets. The seam will have to be reworked if any of these rivets is defective. Suppose rivets are defective independently of one another, each with the same probability. a. If 20% of all seams need reworking, what is the probability that a rivet is defective? b. How small should the probability of a defective rivet be to ensure that only 10% of all seams need reworking? 78. A boiler has five identical relief valves. The probability that any particular valve will open on demand is .95. Assuming independent operation of the valves, calculate P(at least one valve opens) and P(at least one valve fails to open). 79. Two pumps connected in parallel fail independently of one another on any given day. The probability that only the older pump will fail is .10, and the probability that only the newer pump will fail is .05. What is the probability that the pumping system will fail on any given day (which happens if both pumps fail)? 80. Consider the system of components connected as in the accompanying picture. Components 1 and 2 are connected in parallel, so that subsystem works iff either 1 or 2 works; since 3 and 4 are connected in series, that subsystem works iff both 3 and 4 work. If components work independently of 1 2 3 4 87 one another and P(component works) 5 .9, calculate P(system works). 81. Refer back to the series-parallel system configuration introduced in Example 2.35, and suppose that there are only two cells rather than three in each parallel subsystem [in Figure 2.14(a), eliminate cells 3 and 6, and renumber cells 4 and 5 as 3 and 4]. Using P(Ai) 5 .9, the probability that system lifetime exceeds t0 is easily seen to be .9639. To what value would .9 have to be changed in order to increase the system lifetime reliability from .9639 to .99? [Hint: Let P(Ai) 5 p, express system reliability in terms of p, and then let x 5 p2.] 82. Consider independently rolling two fair dice, one red and the other green. Let A be the event that the red die shows 3 dots, B be the event that the green die shows 4 dots, and C be the event that the total number of dots showing on the two dice is 7. Are these events pairwise independent (i.e., are A and B independent events, are A and C independent, and are B and C independent)? Are the three events mutually independent? 83. Components arriving at a distributor are checked for defects by two different inspectors (each component is checked by both inspectors). The first inspector detects 90% of all defectives that are present, and the second inspector does likewise. At least one inspector does not detect a defect on 20% of all defective components. What is the probability that the following occur? a. A defective component will be detected only by the first inspector? By exactly one of the two inspectors? b. All three defective components in a batch escape detection by both inspectors (assuming inspections of different components are independent of one another)? 84. Seventy percent of all vehicles examined at a certain emissions inspection station pass the inspection. Assuming that successive vehicles pass or fail independently of one another, calculate the following probabilities: a. P(all of the next three vehicles inspected pass) b. P(at least one of the next three inspected fails) c. P(exactly one of the next three inspected passes) d. P(at most one of the next three vehicles inspected passes) e. Given that at least one of the next three vehicles passes inspection, what is the probability that all three pass (a conditional probability)? 85. A quality control inspector is inspecting newly produced items for faults. The inspector searches an item for faults in a series of independent fixations, each of a fixed duration. Given that a flaw is actually present, let p denote the probability that the flaw is detected during any one fixation (this model is discussed in “Human Performance in Sampling Inspection,” Human Factors, 1979: 99–105). a. Assuming that an item has a flaw, what is the probability that it is detected by the end of the second fixation (once a flaw has been detected, the sequence of fixations terminates)? b. Give an expression for the probability that a flaw will be detected by the end of the nth fixation. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 88 CHAPTER 2 Probability c. If when a flaw has not been detected in three fixations, the item is passed, what is the probability that a flawed item will pass inspection? d. Suppose 10% of all items contain a flaw [P(randomly chosen item is flawed) 5 .1]. With the assumption of part (c), what is the probability that a randomly chosen item will pass inspection (it will automatically pass if it is not flawed, but could also pass if it is flawed)? e. Given that an item has passed inspection (no flaws in three fixations), what is the probability that it is actually flawed? Calculate for p 5 .5. Suppose that P(A1) 5 .55, P(A2) 5 .65, P(A3) 5 .70, P(A1 ´ A2) 5 .80, P(A2 ¨ A3) 5 .40, and P(A1 ´ A2 ´ A3) 5 .88. a. What is the probability that the individual likes both vehicle #1 and vehicle #2? b. Determine and interpret P( A2 | A3 ). c. Are A2 and A3 independent events? Answer in two different ways. d. If you learn that the individual did not like vehicle #1, what now is the probability that he/she liked at least one of the other two vehicles? 86. a. A lumber company has just taken delivery on a lot of 10,0002 3 4 boards. Suppose that 20% of these boards (2,000) are actually too green to be used in first-quality construction. Two boards are selected at random, one after the other. Let A 5 5the first board is green6 and B 5 5the second board is green6 . Compute P(A), P(B), and P(A ¨ B) (a tree diagram might help). Are A and B independent? b. With A and B independent and P(A) 5 P(B) 5 .2, what is P(A ¨ B)? How much difference is there between this answer and P(A ¨ B) in part (a)? For purposes of calculating P(A ¨ B), can we assume that A and B of part (a) are independent to obtain essentially the correct probability? c. Suppose the lot consists of ten boards, of which two are green. Does the assumption of independence now yield approximately the correct answer for P(A ¨ B)? What is the critical difference between the situation here and that of part (a)? When do you think an independence assumption would be valid in obtaining an approximately correct answer to P(A ¨ B)? 88. Professor Stan der Deviation can take one of two routes on his way home from work. On the first route, there are four railroad crossings. The probability that he will be stopped by a train at any particular one of the crossings is .1, and trains operate independently at the four crossings. The other route is longer but there are only two crossings, independent of one another, with the same stoppage probability for each as on the first route. On a particular day, Professor Deviation has a meeting scheduled at home for a certain time. Whichever route he takes, he calculates that he will be late if he is stopped by trains at at least half the crossings encountered. a. Which route should he take to minimize the probability of being late to the meeting? b. If he tosses a fair coin to decide on a route and he is late, what is the probability that he took the four-crossing route? 87. Consider randomly selecting a single individual and having that person test drive 3 different vehicles. Define events A1, A2, and A3 by A1 5 likes vehicle [1 A3 5 likes vehicle [3 A2 5 likes vehicle [2 SUPPLEMENTARY EXERCISES 89. Suppose identical tags are placed on both the left ear and the right ear of a fox. The fox is then let loose for a period of time. Consider the two events C1 5 5left ear tag is lost6 and C2 5 5right ear tag is lost6 . Let p 5 P(C1) 5 P(C2), and assume C1 and C2 are independent events. Derive an expression (involving ␲) for the probability that exactly one tag is lost, given that at most one is lost (“Ear Tag Loss in Red Foxes,” J. Wildlife Mgmt., 1976: 164–167). [Hint: Draw a tree diagram in which the two initial branches refer to whether the left ear tag was lost.] (90–114) 90. A small manufacturing company will start operating a night shift. There are 20 machinists employed by the company. a. If a night crew consists of 3 machinists, how many different crews are possible? b. If the machinists are ranked 1, 2, . . . , 20 in order of competence, how many of these crews would not have the best machinist? c. How many of the crews would have at least 1 of the 10 best machinists? d. If one of these crews is selected at random to work on a particular night, what is the probability that the best machinist will not work that night? 91. A factory uses three production lines to manufacture cans of a certain type. The accompanying table gives percentages of nonconforming cans, categorized by type of nonconformance, for each of the three lines during a particular time period. Blemish Crack Pull-Tab Problem Surface Defect Other Line 1 Line 2 Line 3 15 50 21 10 4 12 44 28 8 8 20 40 24 15 2 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Supplementary Exercises During this period, line 1 produced 500 nonconforming cans, line 2 produced 400 such cans, and line 3 was responsible for 600 nonconforming cans. Suppose that one of these 1500 cans is randomly selected. a. What is the probability that the can was produced by line 1? That the reason for nonconformance is a crack? b. If the selected can came from line 1, what is the probability that it had a blemish? c. Given that the selected can had a surface defect, what is the probability that it came from line 1? 92. An employee of the records office at a certain university currently has ten forms on his desk awaiting processing. Six of these are withdrawal petitions and the other four are course substitution requests. a. If he randomly selects six of these forms to give to a subordinate, what is the probability that only one of the two types of forms remains on his desk? b. Suppose he has time to process only four of these forms before leaving for the day. If these four are randomly selected one by one, what is the probability that each succeeding form is of a different type from its predecessor? 93. One satellite is scheduled to be launched from Cape Canaveral in Florida, and another launching is scheduled for Vandenberg Air Force Base in California. Let A denote the event that the Vandenberg launch goes off on schedule, and let B represent the event that the Cape Canaveral launch goes off on schedule. If A and B are independent events with P(A) . P(B), P(A ´ B) 5 .626, and P(A ¨ B) 5 .144, determine the values of P(A) and P(B). 94. A transmitter is sending a message by using a binary code, namely, a sequence of 0’s and 1’s. Each transmitted bit (0 or 1) must pass through three relays to reach the receiver. At each relay, the probability is .20 that the bit sent will be different from the bit received (a reversal). Assume that the relays operate independently of one another. Transmitter S Relay 1 S Relay 2 S Relay 3 S Receiver a. If a 1 is sent from the transmitter, what is the probability that a 1 is sent by all three relays? b. If a 1 is sent from the transmitter, what is the probability that a 1 is received by the receiver? [Hint: The eight experimental outcomes can be displayed on a tree diagram with three generations of branches, one generation for each relay.] c. Suppose 70% of all bits sent from the transmitter are 1s. If a 1 is received by the receiver, what is the probability that a 1 was sent? 95. Individual A has a circle of five close friends (B, C, D, E, and F). A has heard a certain rumor from outside the circle and has invited the five friends to a party to circulate the rumor. To begin, A selects one of the five at random and tells the rumor to the chosen individual. That individual then selects at random one of the four remaining individuals and repeats the rumor. Continuing, a new individual is selected from those not already having heard the rumor by 89 the individual who has just heard it, until everyone has been told. a. What is the probability that the rumor is repeated in the order B, C, D, E, and F? b. What is the probability that F is the third person at the party to be told the rumor? c. What is the probability that F is the last person to hear the rumor? d. If at each stage the person who currently “has” the rumor does not know who has already heard it and selects the next recipient at random from all five possible individuals, what is the probability that F has still not heard the rumor after it has been told ten times at the party? 96. According to the article “Optimization of Distribution Parameters for Estimating Probability of Crack Detection” (J. of Aircraft, 2009: 2090–2097), the following “Palmberg” equation is commonly used to determine the probability Pd (c) of detecting a crack of size c in an aircraft structure: Pd (c) 5 (c/c*)b 1 1 (c/c*)b where c* is the crack size that corresponds to a .5 detection probability (and thus is an assessment of the quality of the inspection process). a. Verify that Pd (c*) 5 .5 b. What is Pd (2c*) when b 5 4? c. Suppose an inspector inspects two different panels, one with a crack size of c* and the other with a crack size of 2c*. Again assuming b 5 4 and also that the results of the two inspections are independent of one another, what is the probability that exactly one of the two cracks will be detected? d. What happens to Pd (c) as b S ` ? 97. A chemical engineer is interested in determining whether a certain trace impurity is present in a product. An experiment has a probability of .80 of detecting the impurity if it is present. The probability of not detecting the impurity if it is absent is .90. The prior probabilities of the impurity being present and being absent are .40 and .60, respectively. Three separate experiments result in only two detections. What is the posterior probability that the impurity is present? 98. Each contestant on a quiz show is asked to specify one of six possible categories from which questions will be asked. Suppose P(contestant requests category i) 5 1 and succes6 sive contestants choose their categories independently of one another. If there are three contestants on each show and all three contestants on a particular show select different categories, what is the probability that exactly one has selected category 1? 99. Fasteners used in aircraft manufacturing are slightly crimped so that they lock enough to avoid loosening during vibration. Suppose that 95% of all fasteners pass an initial inspection. Of the 5% that fail, 20% are so seriously defective that they must be scrapped. The remaining fasteners are sent to a recrimping operation, where 40% cannot be Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 90 CHAPTER 2 Probability salvaged and are discarded. The other 60% of these fasteners are corrected by the recrimping process and subsequently pass inspection. a. What is the probability that a randomly selected incoming fastener will pass inspection either initially or after recrimping? b. Given that a fastener passed inspection, what is the probability that it passed the initial inspection and did not need recrimping? 100. One percent of all individuals in a certain population are carriers of a particular disease. A diagnostic test for this disease has a 90% detection rate for carriers and a 5% detection rate for noncarriers. Suppose the test is applied independently to two different blood samples from the same randomly selected individual. a. What is the probability that both tests yield the same result? b. If both tests are positive, what is the probability that the selected individual is a carrier? 101. A system consists of two components. The probability that the second component functions in a satisfactory manner during its design life is .9, the probability that at least one of the two components does so is .96, and the probability that both components do so is .75. Given that the first component functions in a satisfactory manner throughout its design life, what is the probability that the second one does also? 102. A certain company sends 40% of its overnight mail parcels via express mail service E1. Of these parcels, 2% arrive after the guaranteed delivery time (denote the event “late delivery” by L). If a record of an overnight mailing is randomly selected from the company’s file, what is the probability that the parcel went via E1 and was late? 103. Refer to Exercise 102. Suppose that 50% of the overnight parcels are sent via express mail service E2 and the remaining 10% are sent via E3. Of those sent via E2, only 1% arrive late, whereas 5% of the parcels handled by E3 arrive late. a. What is the probability that a randomly selected parcel arrived late? b. If a randomly selected parcel has arrived on time, what is the probability that it was not sent via E1? 104. A company uses three different assembly lines—A1, A2, and A3—to manufacture a particular component. Of those manufactured by line A1, 5% need rework to remedy a defect, whereas 8% of A2’s components need rework and 10% of A3’s need rework. Suppose that 50% of all components are produced by line A1, 30% are produced by line A2, and 20% come from line A3. If a randomly selected component needs rework, what is the probability that it came from line A1? From line A2? From line A3? 105. Disregarding the possibility of a February 29 birthday, suppose a randomly selected individual is equally likely to have been born on any one of the other 365 days. a. If ten people are randomly selected, what is the probability that all have different birthdays? That at least two have the same birthday? b. With k replacing ten in part (a), what is the smallest k for which there is at least a 50-50 chance that two or more people will have the same birthday? c. If ten people are randomly selected, what is the probability that either at least two have the same birthday or at least two have the same last three digits of their Social Security numbers? [Note: The article “Methods for Studying Coincidences” (F. Mosteller and P. Diaconis, J. Amer. Stat. Assoc., 1989: 853–861) discusses problems of this type.] 106. One method used to distinguish between granitic (G) and basaltic (B) rocks is to examine a portion of the infrared spectrum of the sun’s energy reflected from the rock surface. Let R1, R2, and R3 denote measured spectrum intensities at three different wavelengths; typically, for granite R1 , R2 , R3, whereas for basalt R3 , R1 , R2. When measurements are made remotely (using aircraft), various orderings of the Ris may arise whether the rock is basalt or granite. Flights over regions of known composition have yielded the following information: R1 , R2 , R3 R1 , R3 , R2 R3 , R1 , R2 Granite Basalt 60% 25% 15% 10% 20% 70% Suppose that for a randomly selected rock in a certain region, P(granite) 5 .25 and P(basalt) 5 .75. a. Show that P(granite | R1 , R2 , R3) . P(basalt | R1 , R2 , R3). If measurements yielded R1 , R2 , R3, would you classify the rock as granite or basalt? b. If measurements yielded R1 , R3 , R2, how would you classify the rock? Answer the same question for R3 , R1 , R2. c. Using the classification rules indicated in parts (a) and (b), when selecting a rock from this region, what is the probability of an erroneous classification? [Hint: Either G could be classified as B or B as G, and P(B) and P(G) are known.] d. If P(granite) 5 p rather than .25, are there values of p (other than 1) for which one would always classify a rock as granite? 107. A subject is allowed a sequence of glimpses to detect a target. Let Gi 5 5the target is detected on the ith glimpse6 , with pi 5 P(Gi). Suppose the G'i s are independent events, and write an expression for the probability that the target has been detected by the end of the nth glimpse. [Note: This model is discussed in “Predicting Aircraft Detectability,” Human Factors, 1979: 277–291.] 108. In a Little League baseball game, team A’s pitcher throws a strike 50% of the time and a ball 50% of the time, successive pitches are independent of one another, and the pitcher never hits a batter. Knowing this, team B’s manager has instructed the first batter not to swing at anything. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Bibliography Calculate the probability that a. The batter walks on the fourth pitch b. The batter walks on the sixth pitch (so two of the first five must be strikes), using a counting argument or constructing a tree diagram c. The batter walks d. The first batter up scores while no one is out (assuming that each batter pursues a no-swing strategy) 109. Four engineers, A, B, C, and D, have been scheduled for job interviews at 10 A.M. on Friday, January 13, at Random Sampling, Inc. The personnel manager has scheduled the four for interview rooms 1, 2, 3, and 4, respectively. However, the manager’s secretary does not know this, so assigns them to the four rooms in a completely random fashion (what else!). What is the probability that a. All four end up in the correct rooms? b. None of the four ends up in the correct room? 110. A particular airline has 10 A.M. flights from Chicago to New York, Atlanta, and Los Angeles. Let A denote the event that the New York flight is full and define events B and C analogously for the other two flights. Suppose P(A) 5 .6, P(B) 5 .5, P(C) 5 .4 and the three events are independent. What is the probability that a. All three flights are full? That at least one flight is not full? b. Only the New York flight is full? That exactly one of the three flights is full? 111. A personnel manager is to interview four candidates for a job. These are ranked 1, 2, 3, and 4 in order of preference and will be interviewed in random order. However, at the conclusion of each interview, the manager will know only how the current candidate compares to those previously interviewed. For example, the interview order 3, 4, 1, 2 generates no information after the first interview, shows 91 that the second candidate is worse than the first, and that the third is better than the first two. However, the order 3, 4, 2, 1 would generate the same information after each of the first three interviews. The manager wants to hire the best candidate but must make an irrevocable hire/no hire decision after each interview. Consider the following strategy: Automatically reject the first s candidates and then hire the first subsequent candidate who is best among those already interviewed (if no such candidate appears, the last one interviewed is hired). For example, with s 5 2, the order 3, 4, 1, 2 would result in the best being hired, whereas the order 3, 1, 2, 4 would not. Of the four possible s values (0, 1, 2, and 3), which one maximizes P(best is hired)? [Hint: Write out the 24 equally likely interview orderings: s 5 0 means that the first candidate is automatically hired.] 112. Consider four independent events A1, A2, A3, and A4, and let pi 5 P(Ai) for i 5 1,2,3,4. Express the probability that at least one of these four events occurs in terms of the pis, and do the same for the probability that at least two of the events occur. 113. A box contains the following four slips of paper, each having exactly the same dimensions: (1) win prize 1; (2) win prize 2; (3) win prize 3; (4) win prizes 1, 2, and 3. One slip will be randomly selected. Let A1 5 5win prize 16 , A2 5 5win prize 26 , and A3 5 5win prize 36 . Show that A1 and A2 are independent, that A1 and A3 are independent, and that A2 and A3 are also independent (this is pairwise independence). However, show that P(A1 ¨ A2 ¨ A3) 2 P(A1) ? P(A2) ? P(A3), so the three events are not mutually independent. 114. Show that if A1, A2, and A3 are independent events, then P(A1 | A2 ¨ A3) 5 P(A1). Bibliography Durrett, Richard, Elementary Probability for Applications, Cambridge Univ. Press, London, England, 2009. A concise but readable presentation at a slightly higher level than this text. Mosteller, Frederick, Robert Rourke, and George Thomas, Probability with Statistical Applications (2nd ed.), AddisonWesley, Reading, MA, 1970. A very good precalculus introduction to probability, with many entertaining examples; especially good on counting rules and their application. Olkin, Ingram, Cyrus Derman, and Leon Gleser, Probability Models and Application (2nd ed.), Macmillan, New York, 1994. A comprehensive introduction to probability, written at a slightly higher mathematical level than this text but containing many good examples. Ross, Sheldon, A First Course in Probability (8th ed.), Macmillan, New York, 2009. Rather tightly written and more mathematically sophisticated than this text but contains a wealth of interesting examples and exercises. Winkler, Robert, Introduction to Bayesian Inference and Decision, Holt, Rinehart & Winston, New York, 1972. A very good introduction to subjective probability. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3 Discrete Random Variables and Probability Distributions INTRODUCTION Whether an experiment yields qualitative or quantitative outcomes, methods of statistical analysis require that we focus on certain numerical aspects of the data (such as a sample proportion x/n, mean x, or standard deviations). The concept of a random variable allows us to pass from the experimental outcomes themselves to a numerical function of the outcomes. There are two fundamentally different types of random variables—discrete random variables and continuous random variables. In this chapter, we examine the basic properties and discuss the most important examples of discrete variables. Chapter 4 focuses on continuous random variables. 92 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.1. Random Variables 93 3.1 Random Variables In any experiment, there are numerous characteristics that can be observed or measured, but in most cases an experimenter will focus on some specific aspect or aspects of a sample. For example, in a study of commuting patterns in a metropolitan area, each individual in a sample might be asked about commuting distance and the number of people commuting in the same vehicle, but not about IQ, income, family size, and other such characteristics. Alternatively, a researcher may test a sample of components and record only the number that have failed within 1000 hours, rather than record the individual failure times. In general, each outcome of an experiment can be associated with a number by specifying a rule of association (e.g., the number among the sample of ten components that fail to last 1000 hours or the total weight of baggage for a sample of 25 airline passengers). Such a rule of association is called a random variable—a variable because different numerical values are possible and random because the observed value depends on which of the possible experimental outcomes results (Figure 3.1). ⫺2 ⫺1 0 Figure 3.1 DEFINITION 1 2 A random variable For a given sample space S of some experiment, a random variable (rv) is any rule that associates a number with each outcome in S . In mathematical language, a random variable is a function whose domain is the sample space and whose range is the set of real numbers. Random variables are customarily denoted by uppercase letters, such as X and Y, near the end of our alphabet. In contrast to our previous use of a lowercase letter, such as x, to denote a variable, we will now use lowercase letters to represent some particular value of the corresponding random variable. The notation X(s) 5 x means that x is the value associated with the outcome s by the rv X. Example 3.1 When a student calls a university help desk for technical support, he/she will either immediately be able to speak to someone (S, for success) or will be placed on hold (F, for failure). With S 5 5S, F6 , define an rv X by X(S) 5 1 X(F) 5 0 The rv X indicates whether (1) or not (0) the student can immediately speak to someone. ■ The rv X in Example 3.1 was specified by explicitly listing each element of S and the associated number. Such a listing is tedious if S contains more than a few outcomes, but it can frequently be avoided. Example 3.2 Consider the experiment in which a telephone number in a certain area code is dialed using a random number dialer (such devices are used extensively by polling organizations), and define an rv Y by Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 94 CHAPTER 3 Discrete Random Variables and Probability Distributions Y5 e 1 0 if the selected number is unlisted if the selected number is listed in the directory For example, if 5282966 appears in the telephone directory, then Y(5282966) 5 0, whereas Y(7727350) 5 1 tells us that the number 7727350 is unlisted. A word description of this sort is more economical than a complete listing, so we will use such a description whenever possible. ■ In Examples 3.1 and 3.2, the only possible values of the random variable were 0 and 1. Such a random variable arises frequently enough to be given a special name, after the individual who first studied it. DEFINITION Any random variable whose only possible values are 0 and 1 is called a Bernoulli random variable. We will sometimes want to consider several different random variables from the same sample space. Example 3.3 Example 2.3 described an experiment in which the number of pumps in use at each of two six-pump gas stations was determined. Define rv’s X, Y, and U by X 5 the total number of pumps in use at the two stations Y 5 the difference between the number of pumps in use at station 1 and the number in use at station 2 U 5 the maximum of the numbers of pumps in use at the two stations If this experiment is performed and s 5 (2, 3) results, then X((2, 3)) 5 2 1 3 5 5, so we say that the observed value of X was x 5 5. Similarly, the observed value of Y would be y 5 2 2 3 5 21, and the observed value of U would be u 5 max (2, 3) 5 3. ■ Each of the random variables of Examples 3.1–3.3 can assume only a finite number of possible values. This need not be the case. Example 3.4 Consider an experiment in which 9-volt batteries are tested until one with an acceptable voltage (S ) is obtained. The sample space is S 5 5S, FS, FFS, c6 . Define an rv X by X 5 the number of batteries tested before the experiment terminates Then X(S) 5 1, X(FS) 5 2, X(FFS) 5 3, c, X(FFFFFFS) 5 7, and so on. Any positive integer is a possible value of X, so the set of possible values is infinite. ■ Example 3.5 Suppose that in some random fashion, a location (latitude and longitude) in the continental United States is selected. Define an rv Y by Y 5 the height above sea level at the selected location For example, if the selected location were (39°50⬘N, 98°35⬘W), then we might have Y((39850rN, 98835rW)) 5 1748.26 ft. The largest possible value of Y is 14,494 (Mt. Whitney), and the smallest possible value is 2282 (Death Valley). The set of all possible values of Y is the set of all numbers in the interval between 2282 and 14,494—that is, 5y : y is a number, 2282 # y # 14,4946 and there are an infinite number of numbers in this interval. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.1. Random Variables 95 Two Types of Random Variables In Section 1.2, we distinguished between data resulting from observations on a counting variable and data obtained by observing values of a measurement variable. A slightly more formal distinction characterizes two different types of random variables. DEFINITION A discrete random variable is an rv whose possible values either constitute a finite set or else can be listed in an infinite sequence in which there is a first element, a second element, and so on (“countably” infinite). A random variable is continuous if both of the following apply: 1. Its set of possible values consists either of all numbers in a single interval on the number line (possibly infinite in extent, e.g., from 2` to ⬁) or all numbers in a disjoint union of such intervals (e.g., [0, 10] ´ [20, 30]). 2. No possible value of the variable has positive probability, that is, P(X 5 c) 5 0 for any possible value c. Although any interval on the number line contains an infinite number of numbers, it can be shown that there is no way to create an infinite listing of all these values— there are just too many of them. The second condition describing a continuous random variable is perhaps counterintuitive, since it would seem to imply a total probability of zero for all possible values. But we shall see in Chapter 4 that intervals of values have positive probability; the probability of an interval will decrease to zero as the width of the interval shrinks to zero. Example 3.6 All random variables in Examples 3.1 –3.4 are discrete. As another example, suppose we select married couples at random and do a blood test on each person until we find a husband and wife who both have the same Rh factor. With X 5 the number of blood tests to be performed, possible values of X are D 5 52, 4, 6, 8, c6 . Since the possible values have been listed in sequence, X is a discrete rv. ■ To study basic properties of discrete rv’s, only the tools of discrete mathematics— summation and differences—are required. The study of continuous variables requires the continuous mathematics of the calculus—integrals and derivatives. EXERCISES Section 3.1 (1–10) 1. A concrete beam may fail either by shear (S) or flexure (F). Suppose that three failed beams are randomly selected and the type of failure is determined for each one. Let X 5 the number of beams among the three selected that failed by shear. List each outcome in the sample space along with the associated value of X. 5. If the sample space S is an infinite set, does this necessarily imply that any rv X defined from S will have an infinite set of possible values? If yes, say why. If no, give an example. 3. Using the experiment in Example 3.3, define two more random variables and list the possible values of each. 6. Starting at a fixed time, each car entering an intersection is observed to see whether it turns left (L), right (R), or goes straight ahead (A). The experiment terminates as soon as a car is observed to turn left. Let X 5 the number of cars observed. What are possible X values? List five outcomes and their associated X values. 4. Let X 5 the number of nonzero digits in a randomly selected zip code. What are the possible values of X? Give three possible outcomes and their associated X values. 7. For each random variable defined here, describe the set of possible values for the variable, and state whether the variable is discrete. 2. Give three examples of Bernoulli rv’s (other than those in the text). Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 96 CHAPTER 3 Discrete Random Variables and Probability Distributions a. X 5 the number of unbroken eggs in a randomly chosen standard egg carton b. Y 5 the number of students on a class list for a particular course who are absent on the first day of classes c. U 5 the number of times a duffer has to swing at a golf ball before hitting it d. X 5 the length of a randomly selected rattlesnake e. Z 5 the amount of royalties earned from the sale of a first edition of 10,000 textbooks f. Y 5 the pH of a randomly chosen soil sample g. X 5 the tension (psi) at which a randomly selected tennis racket has been strung h. X 5 the total number of coin tosses required for three individuals to obtain a match (HHH or TTT) 8. Each time a component is tested, the trial is a success (S) or failure (F). Suppose the component is tested repeatedly until a success occurs on three consecutive trials. Let Y denote the number of trials necessary to achieve this. List all outcomes corresponding to the five smallest possible values of Y, and state which Y value is associated with each one. 9. An individual named Claudius is located at the point 0 in the accompanying diagram. A2 B1 B2 A3 B4 10. The number of pumps in use at both a six-pump station and a four-pump station will be determined. Give the possible values for each of the following random variables: a. T 5 the total number of pumps in use b. X 5 the difference between the numbers in use at stations 1 and 2 c. U 5 the maximum number of pumps in use at either station d. Z 5 the number of stations having exactly two pumps in use B3 0 A1 Using an appropriate randomization device (such as a tetrahedral die, one having four sides), Claudius first moves to one of the four locations B1, B2, B3, B4. Once at one of these locations, another randomization device is used to decide whether Claudius next returns to 0 or next visits one of the other two adjacent points. This process then continues; after each move, another move to one of the (new) adjacent points is determined by tossing an appropriate die or coin. a. Let X 5 the number of moves that Claudius makes before first returning to 0. What are possible values of X? Is X discrete or continuous? b. If moves are allowed also along the diagonal paths connecting 0 to A1, A2, A3, and A4, respectively, answer the questions in part (a). A4 3.2 Probability Distributions for Discrete Random Variables Probabilities assigned to various outcomes in S in turn determine probabilities associated with the values of any particular rv X. The probability distribution of X says how the total probability of 1 is distributed among (allocated to) the various possible X values. Suppose, for example, that a business has just purchased four laser printers, and let X be the number among these that require service during the warranty period. Possible X values are then 0, 1, 2, 3, and 4. The probability distribution will tell us how the probability of 1 is subdivided among these five possible values— how much probability is associated with the X value 0, how much is apportioned to the X value 1, and so on. We will use the following notation for the probabilities in the distribution: p(0) 5 the probability of the X value 0 5 P(X 5 0) p(1) 5 the probability of the X value 1 5 P(X 5 1) and so on. In general, p(x) will denote the probability assigned to the value x. Example 3.7 The Cal Poly Department of Statistics has a lab with six computers reserved for statistics majors. Let X denote the number of these computers that are in use at a particular time of day. Suppose that the probability distribution of X is as given in the Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.2. Probability Distributions for Discrete Random Variables 97 following table; the first row of the table lists the possible X values and the second row gives the probability of each such value. x 0 1 2 3 4 5 6 p(x) .05 .10 .15 .25 .20 .15 .10 We can now use elementary probability properties to calculate other probabilities of interest. For example, the probability that at most 2 computers are in use is P(X # 2) 5 P(X 5 0 or 1 or 2) 5 p(0) 1 p(1) 1 p(2) 5 .05 1 .10 1 .15 5 .30 Since the event at least 3 computers are in use is complementary to at most 2 computers are in use, P(X $ 3) 5 1 2 P(X # 2) 5 1 2 .30 5 .70 which can, of course, also be obtained by adding together probabilities for the values, 3, 4, 5, and 6. The probability that between 2 and 5 computers inclusive are in use is P(2 # X # 5) 5 P(X 5 2, 3, 4, or 5) 5 .15 1 .25 1 .20 1 .15 5 .75 whereas the probability that the number of computers in use is strictly between 2 and 5 is P(2 , X , 5) 5 P(X 5 3 or 4) 5 .25 1 .20 5 .45 DEFINITION ■ The probability distribution or probability mass function (pmf) of a discrete rv is defined for every number x by p(x) 5 P(X 5 x) 5 P(all s 僆 S : X(s) 5 x). In words, for every possible value x of the random variable, the pmf specifies the probability of observing that value when the experiment is performed. The conditions p(x) $ 0 and g all possible x p(x) 5 1 are required of any pmf. The pmf of X in the previous example was simply given in the problem description. We now consider several examples in which various probability properties are exploited to obtain the desired distribution. Example 3.8 Six lots of components are ready to be shipped by a certain supplier. The number of defective components in each lot is as follows: Lot Number of defectives 1 2 3 4 5 6 0 2 0 1 2 0 One of these lots is to be randomly selected for shipment to a particular customer. Let X be the number of defectives in the selected lot. The three possible X values are 0, 1, and 2. Of the six equally likely simple events, three result in X 5 0, one in X 5 1, and the other two in X 5 2. Then p(0) 5 P(X 5 0) 5 P(lot 1 or 3 or 6 is sent) 5 3 5 .500 6 1 5 .167 6 2 p(2) 5 P(X 5 2) 5 P(lot 2 or 5 is sent) 5 5 .333 6 p(1) 5 P(X 5 1) 5 P(lot 4 is sent) 5 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 98 CHAPTER 3 Discrete Random Variables and Probability Distributions That is, a probability of .500 is distributed to the X value 0, a probability of .167 is placed on the X value 1, and the remaining probability, .333, is associated with the X value 2. The values of X along with their probabilities collectively specify the pmf. If this experiment were repeated over and over again, in the long run X 5 0 would occur one-half of the time, X 5 1 one-sixth of the time, and X 5 2 one-third of the time. ■ Example 3.9 Consider whether the next person buying a computer at a certain electronics store buys a laptop or a desktop model. Let X5 e 1 0 if the customer purchases a desktop computer if the customer purchases a laptop computer If 20% of all purchasers during that week select a desktop, the pmf for X is p(0) 5 P(X 5 0) 5 P(next customer purchases a laptop model) 5 .8 p(1) 5 P(X 5 1) 5 P(next customer purchases a desktop model) 5 .2 p(x) 5 P(X 5 x) 5 0 for x 2 0 or 1 An equivalent description is .8 p(x) 5 c.2 0 if x 5 0 if x 5 1 if x 2 0 or 1 Figure 3.2 is a picture of this pmf, called a line graph. X is, of course, a Bernoulli rv and p(x) is a Bernoulli pmf. p(x) 1 x 0 Figure 3.2 Example 3.10 1 The line graph for the pmf in Example 3.9 ■ Consider a group of five potential blood donors—a, b, c, d, and e—of whom only a and b have type O1 blood. Five blood samples, one from each individual, will be typed in random order until an O1 individual is identified. Let the rv Y 5 the number of typings necessary to identify an O1 individual. Then the pmf of Y is 2 5 .4 5 p(2) 5 P(Y 5 2) 5 P(c, d, or e first, and then a or b) p(1) 5 P(Y 5 1) 5 P(a or b typed first) 5 3 # 2 5 .3 5 4 P(Y 5 3) 5 P(c, d, or e first and second, and then a or b) 3 2 2 a b a b a b 5 .2 5 4 3 3 2 1 P(Y 5 4) 5 P(c, d, and e all done first) 5 a b a b a b 5 .1 5 4 3 0 if y 2 1, 2, 3, 4 5 P(c, d, or e first) # P(a or b next | c, d, or e first) 5 p(3) 5 5 p(4) 5 p(y) 5 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.2. Probability Distributions for Discrete Random Variables 99 In tabular form, the pmf is y 1 2 3 4 p(y) .4 .3 .2 .1 where any y value not listed receives zero probability. Figure 3.3 shows a line graph of the pmf. p(y) .5 y 0 Figure 3.3 1 2 3 4 The line graph for the pmf in Example 3.10 ■ The name “probability mass function” is suggested by a model used in physics for a system of “point masses.” In this model, masses are distributed at various locations x along a one-dimensional axis. Our pmf describes how the total probability mass of 1 is distributed at various points along the axis of possible values of the random variable (where and how much mass at each x). Another useful pictorial representation of a pmf, called a probability histogram, is similar to histograms discussed in Chapter 1. Above each y with p(y) . 0, construct a rectangle centered at y. The height of each rectangle is proportional to p(y), and the base is the same for all rectangles. When possible values are equally spaced, the base is frequently chosen as the distance between successive y values (though it could be smaller). Figure 3.4 shows two probability histograms. 0 1 1 2 (a) Figure 3.4 3 4 (b) Probability histograms: (a) Example 3.9; (b) Example 3.10 It is often helpful to think of a pmf as specifying a mathematical model for a discrete population. Example 3.11 Consider selecting at random a student who is among the 15,000 registered for the current term at Mega University. Let X 5 the number of courses for which the selected student is registered, and suppose that X has the following pmf: x p(x) 1 2 3 4 5 6 7 .01 .03 .13 .25 .39 .17 .02 One way to view this situation is to think of the population as consisting of 15,000 individuals, each having his or her own X value; the proportion with each X value is given by p(x). An alternative viewpoint is to forget about the students and think of the population itself as consisting of the X values: There are some 1s in the population, some 2s, . . . , and finally some 7s. The population then consists of the numbers 1, 2, . . . , 7 (so is discrete), and p(x) gives a model for the distribution of population values. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 100 CHAPTER 3 Discrete Random Variables and Probability Distributions Once we have such a population model, we will use it to compute values of population characteristics (e.g., the mean m) and make inferences about such characteristics. A Parameter of a Probability Distribution The pmf of the Bernoulli rv X in Example 3.9 was p(0) 5 .8 and p(1) 5 .2 because 20% of all purchasers selected a desktop computer. At another store, it may be the case that p(0) 5 .9 and p(1) 5 .1. More generally, the pmf of any Bernoulli rv can be expressed in the form p(1) 5 a and p(0) 5 1 2 a, where 0 , a , 1. Because the pmf depends on the particular value of a, we often write p(x; a) rather than just p(x): p(x; a) 5 c 1 2 a if x 5 0 a if x 5 1 0 otherwise (3.1) Then each choice of a in Expression (3.1) yields a different pmf. DEFINITION Suppose p(x) depends on a quantity that can be assigned any one of a number of possible values, with each different value determining a different probability distribution. Such a quantity is called a parameter of the distribution. The collection of all probability distributions for different values of the parameter is called a family of probability distributions. The quantity a in Expression (3.1) is a parameter. Each different number a between 0 and 1 determines a different member of the Bernoulli family of distributions. Example 3.12 Starting at a fixed time, we observe the gender of each newborn child at a certain hospital until a boy (B) is born. Let p 5 P(B), assume that successive births are independent, and define the rv X by x 5 number of births observed. Then p(1) 5 P(X 5 1) 5 P(B) 5 p p(2) 5 P(X 5 2) 5 P(GB) 5 P(G) # P(B) 5 (1 2 p)p and p(3) 5 P(X 5 3) 5 P(GGB) 5 P(G) # P(G) # P(B) 5 (1 2 p)2p Continuing in this way, a general formula emerges: p(x) 5 e (1 2 p)x21p x 5 1, 2, 3, c 0 otherwise (3.2) The parameter p can assume any value between 0 and 1. Expression (3.2) describes the family of geometric distributions. In the gender example, p 5 .51 might be appropriate, but if we were looking for the first child with Rh-positive blood, then we might have p 5.85 . ■ The Cumulative Distribution Function For some fixed value x, we often wish to compute the probability that the observed value of X will be at most x. For example, the pmf in Example 3.8 was Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.2. Probability Distributions for Discrete Random Variables 101 .500 x50 .167 x51 p(x) 5 d .333 x52 0 otherwise The probability that X is at most 1 is then P(X # 1) 5 p(0) 1 p(1) 5 .500 1 .167 5 .667 In this example, X # 1.5 if and only if X # 1, so P(X # 1.5) 5 P(X # 1) 5 .667 Similarly, P(X # 0) 5 P(X 5 0) 5 .5, P(X # .75) 5 .5 And in fact for any x satisfying 0 # x , 1, P(X # x) 5 .5. The largest possible X value is 2, so P(X # 2) 5 1, P(X # 3.7) 5 1, P(X # 20.5) 5 1 and so on. Notice that P(X , 1) , P(X # 1) since the latter includes the probability of the X value 1, whereas the former does not. More generally, when X is discrete and x is a possible value of the variable, P(X , x) , P(X # x). DEFINITION The cumulative distribution function (cdf) F(x) of a discrete rv variable X with pmf p(x) is defined for every number x by F(x) 5 P(X # x) 5 g p(y) (3.3) y:y#x For any number x, F(x) is the probability that the observed value of X will be at most x. Example 3.13 A store carries flash drives with either 1 GB, 2 GB, 4 GB, 8 GB, or 16 GB of memory. The accompanying table gives the distribution of Y 5 the amount of memory in a purchased drive: y p(y) 1 2 4 8 16 .05 .10 .35 .40 .10 Let’s first determine F(y) for each of the five possible values of Y: F(1) F(2) F(4) F(8) F(16) 5 5 5 5 5 P(Y # 1) 5 P(Y 5 1) 5 p(1) 5 .05 P(Y # 2) 5 P(Y 5 1 or 2) 5 p(1) 1 p(2) 5 .15 P(Y # 4) 5 P(Y 5 1 or 2 or 4) 5 p(1) 1 p(2) 1 p(4) 5 .50 P(Y # 8) 5 p(1) 1 p(2) 1 p(4) 1 p(8) 5 .90 P(Y # 16) 5 1 Now for any other number y, F(y) will equal the value of F at the closest possible value of Y to the left of y. For example, F(2.7) 5 P(Y # 2.7) 5 P(Y # 2) 5 F(2) 5 .15 F(7.999) 5 P(Y # 7.999) 5 P(Y # 4) 5 F(4) 5 .50 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 102 CHAPTER 3 Discrete Random Variables and Probability Distributions If y is less than 1, F(y) 5 0 [e.g. F(.58) 5 0], and if y is at least 16, F(y) 5 1 [e.g. F(25) 5 1]. The cdf is thus 0 y,1 .05 1 # y , 2 .15 2 # y , 4 F(y) 5 f .50 4 # y , 8 .90 8 # y , 16 1 16 # y A graph of this cdf is shown in Figure 3.5. F(y) 1.0 0.8 0.6 0.4 0.2 0.0 y 0 5 10 15 Figure 3.5 A graph of the cdf of Example 3.13 20 ■ For X a discrete rv, the graph of F(x) will have a jump at every possible value of X and will be flat between possible values. Such a graph is called a step function. Example 3.14 (Example 3.12 continued) The pmf of X 5 the number of births had the form p(x) 5 e (1 2 p)x21p x 5 1, 2, 3, . . . 0 otherwise For any positive integer x, F(x) 5 x x21 y 51 y50 g p(y) 5 g (1 2 p)y21 p 5 p g (1 2 p)y y#x (3.4) To evaluate this sum, recall that the partial sum of a geometric series is k g ay 5 y50 1 2 a k11 12a Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.2. Probability Distributions for Discrete Random Variables 103 Using this in Equation (3.4), with a 5 1 2 p and k 5 x 2 1, gives F(x) 5 p # 1 2 (1 2 p)x 5 1 2 (1 2 p)x 1 2 (1 2 p) x a positive integer Since F is constant in between positive integers, F(x) 5 e 0 x,1 1 2 (1 2 p)[x] x $ 1 (3.5) where [x] is the largest integer # x (e.g., [2.7] 5 2). Thus if p 5 .51 as in the birth example, then the probability of having to examine at most five births to see the first boy is F(5) 5 1 2 (.49)5 5 1 2 .0282 5 .9718, whereas F(10) < 1.0000. This cdf is graphed in Figure 3.6. F(x) 1.0 x 0 1 2 Figure 3.6 3 4 5 50 51 A graph of F(x) for Example 3.14 ■ In examples thus far, the cdf has been derived from the pmf. This process can be reversed to obtain the pmf from the cdf whenever the latter function is available. For example, consider again the rv of Example 3.7 (the number of computers being used in a lab); possible X values are 0, 1, . . . , 6. Then p(3) 5 5 5 5 P(X 5 3) [p(0) 1 p(1) 1 p(2) 1 p(3)] 2 [p(0) 1 p(1) 1 p(2)] P(X # 3) 2 P(X # 2) F(3) 2 F(2) More generally, the probability that X falls in a specified interval is easily obtained from the cdf. For example, P(2 # X # 4) 5 5 5 5 p(2) 1 p(3) 1 p(4) [p(0) 1 c 1 p(4)] 2 [p(0) 1 p(1)] P(X # 4) 2 P(X # 1) F(4) 2 F(1) Notice that P(2 # X # 4) 2 F(4) 2 F(2). This is because the X value 2 is included in 2 # X # 4, so we do not want to subtract out its probability. However, P(2 , X # 4) 5 F(4) 2 F(2) because X 5 2 is not included in the interval 2 , X # 4. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 104 CHAPTER 3 Discrete Random Variables and Probability Distributions PROPOSITION For any two numbers a and b with a # b, P(a # X # b) 5 F(b) 2 F(a2) where “a2” represents the largest possible X value that is strictly less than a. In particular, if the only possible values are integers and if a and b are integers, then P(a # X # b) 5 P(X 5 a or a 1 1 orc or b) 5 F(b) 2 F(a 2 1) Taking a 5 b yields P(X 5 a) 5 F(a) 2 F(a 2 1) in this case. The reason for subtracting F(a2) rather than F(a) is that we want to include P(X 5 a); F(b) 2 F(a) gives P(a , X # b). This proposition will be used extensively when computing binomial and Poisson probabilities in Sections 3.4 and 3.6. Example 3.15 Let X 5 the number of days of sick leave taken by a randomly selected employee of a large company during a particular year. If the maximum number of allowable sick days per year is 14, possible values of X are 0, 1, . . . , 14. With F(0) 5 .58, F(1) 5 .72, F(2) 5 .76, F(3) 5 .81, F(4) 5 .88, and F(5) 5 .94, P(2 # X # 5) 5 P(X 5 2, 3, 4, or 5) 5 F(5) 2 F(1) 5 .22 and ■ P(X 5 3) 5 F(3) 2 F(2) 5 .05 EXERCISES Section 3.2 (11–28) 11. An automobile service facility specializing in engine tune-ups knows that 45% of all tune-ups are done on fourcylinder automobiles, 40% on six-cylinder automobiles, and 15% on eight-cylinder automobiles. Let X 5 the number of cylinders on the next car to be tuned. a. What is the pmf of X? b. Draw both a line graph and a probability histogram for the pmf of part (a). c. What is the probability that the next car tuned has at least six cylinders? More than six cylinders? 12. Airlines sometimes overbook flights. Suppose that for a plane with 50 seats, 55 passengers have tickets. Define the random variable Y as the number of ticketed passengers who actually show up for the flight. The probability mass function of Y appears in the accompanying table. y 45 46 47 48 49 50 51 52 53 54 55 p(y) .05 .10 .12 .14 .25 .17 .06 .05 .03 .02 .01 a. What is the probability that the flight will accommodate all ticketed passengers who show up? b. What is the probability that not all ticketed passengers who show up can be accommodated? c. If you are the first person on the standby list (which means you will be the first one to get on the plane if there are any seats available after all ticketed passengers have been accommodated), what is the probability that you will be able to take the flight? What is this probability if you are the third person on the standby list? 13. A mail-order computer business has six telephone lines. Let X denote the number of lines in use at a specified time. Suppose the pmf of X is as given in the accompanying table. x p(x) 0 1 2 3 4 5 6 .10 .15 .20 .25 .20 .06 .04 Calculate the probability of each of the following events. a. {at most three lines are in use} b. {fewer than three lines are in use} c. {at least three lines are in use} d. {between two and five lines, inclusive, are in use} e. {between two and four lines, inclusive, are not in use} f. {at least four lines are not in use} Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.2. Probability Distributions for Discrete Random Variables 14. A contractor is required by a county planning department to submit one, two, three, four, or five forms (depending on the nature of the project) in applying for a building permit. Let Y 5 the number of forms required of the next applicant. The probability that y forms are required is known to be proportional to y—that is, p(y) 5 ky for y 5 1, . . . , 5. 5 a. What is the value of k? [Hint: a p(y) 5 1.] y51 b. What is the probability that at most three forms are required? c. What is the probability that between two and four forms (inclusive) are required? d. Could p(y) 5 y2/50 for y 5 1, c, 5 be the pmf of Y? 15. Many manufacturers have quality control programs that include inspection of incoming materials for defects. Suppose a computer manufacturer receives computer boards in lots of five. Two boards are selected from each lot for inspection. We can represent possible outcomes of the selection process by pairs. For example, the pair (1, 2) represents the selection of boards 1 and 2 for inspection. a. List the ten different possible outcomes. b. Suppose that boards 1 and 2 are the only defective boards in a lot of five. Two boards are to be chosen at random. Define X to be the number of defective boards observed among those inspected. Find the probability distribution of X. c. Let F(x) denote the cdf of X. First determine F(0) 5 P(X # 0), F(1), and F(2); then obtain F(x) for all other x. 16. Some parts of California are particularly earthquake-prone. Suppose that in one metropolitan area, 25% of all homeowners are insured against earthquake damage. Four homeowners are to be selected at random; let X denote the number among the four who have earthquake insurance. a. Find the probability distribution of X. [Hint: Let S denote a homeowner who has insurance and F one who does not. Then one possible outcome is SFSS, with probability (.25)(.75)(.25)(.25) and associated X value 3. There are 15 other outcomes.] b. Draw the corresponding probability histogram. c. What is the most likely value for X? d. What is the probability that at least two of the four selected have earthquake insurance? 17. A new battery’s voltage may be acceptable (A) or unacceptable (U). A certain flashlight requires two batteries, so batteries will be independently selected and tested until two acceptable ones have been found. Suppose that 90% of all batteries have acceptable voltages. Let Y denote the number of batteries that must be tested. a. What is p(2), that is, P(Y 5 2)? b. What is p(3)? [Hint: There are two different outcomes that result in Y 5 3.] c. To have Y 5 5, what must be true of the fifth battery selected? List the four outcomes for which Y 5 5 and then determine p(5). d. Use the pattern in your answers for parts (a)–(c) to obtain a general formula for p(y). 105 18. Two fair six-sided dice are tossed independently. Let M 5 the maximum of the two tosses (so M(1,5) 5 5, M(3,3) 5 3, etc.). a. What is the pmf of M? [Hint: First determine p(1), then p(2), and so on.] b. Determine the cdf of M and graph it. 19. A library subscribes to two different weekly news magazines, each of which is supposed to arrive in Wednesday’s mail. In actuality, each one may arrive on Wednesday, Thursday, Friday, or Saturday. Suppose the two arrive independently of one another, and for each one P(Wed.) 5 .3, P(Thurs.) 5 .4, P(Fri.) 5 .2, and P(Sat.) 5 .1. Let Y 5 the number of days beyond Wednesday that it takes for both magazines to arrive (so possible Y values are 0, 1, 2, or 3). Compute the pmf of Y. [Hint: There are 16 possible outcomes; Y(W,W) 5 0, Y(F,Th) 5 2, and so on.] 20. Three couples and two single individuals have been invited to an investment seminar and have agreed to attend. Suppose the probability that any particular couple or individual arrives late is .4 (a couple will travel together in the same vehicle, so either both people will be on time or else both will arrive late). Assume that different couples and individuals are on time or late independently of one another. Let X 5 the number of people who arrive late for the seminar. a. Determine the probability mass function of X. [Hint: label the three couples #1, #2, and #3 and the two individuals #4 and #5.] b. Obtain the cumulative distribution function of X, and use it to calculate P(2 # X # 6). 21. Suppose that you read through this year’s issues of the New York Times and record each number that appears in a news article—the income of a CEO, the number of cases of wine produced by a winery, the total charitable contribution of a politician during the previous tax year, the age of a celebrity, and so on. Now focus on the leading digit of each number, which could be 1, 2, . . . , 8, or 9. Your first thought might be that the leading digit X of a randomly selected number would be equally likely to be one of the nine possibilities (a discrete uniform distribution). However, much empirical evidence as well as some theoretical arguments suggest an alternative probability distribution called Benford’s law: x11 b x p(x) 5 P(1st digit is x) 5 log10 a x 5 1, 2, . . . , 9 a. Without computing individual probabilities from this formula, show that it specifies a legitimate pmf. b. Now compute the individual probabilities and compare to the corresponding discrete uniform distribution. c. Obtain the cdf of X. d. Using the cdf, what is the probability that the leading digit is at most 3? At least 5? [Note: Benford’s law is the basis for some auditing procedures used to detect fraud in financial reporting—for example, by the Internal Revenue Service.] Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 106 CHAPTER 3 Discrete Random Variables and Probability Distributions 26. Alvie Singer lives at 0 in the accompanying diagram and has four friends who live at A, B, C, and D. One day Alvie decides to go visiting, so he tosses a fair coin twice to decide which of the four to visit. Once at a friend’s house, he will either return home or else proceed to one of the two adjacent houses (such as 0, A, or C when at B), with each of the three possibilities having probability 1 . In 3 this way, Alvie continues to visit friends until he returns home. 22. Refer to Exercise 13, and calculate and graph the cdf F(x). Then use it to calculate the probabilities of the events given in parts (a)–(d) of that problem. 23. A consumer organization that evaluates new automobiles customarily reports the number of major defects in each car examined. Let X denote the number of major defects in a randomly selected car of a certain type. The cdf of X is as follows: 0 .06 .19 .39 F(x) 5 h .67 .92 .97 1 x,0 0#x, 1#x, 2#x, 3#x, 4#x, 5#x, 6#x 1 2 3 4 5 6 A 0 D C a. Let X 5 the number of times that Alvie visits a friend. Derive the pmf of X. b. Let Y 5 the number of straight-line segments that Alvie traverses (including those leading to and from 0). What is the pmf of Y? c. Suppose that female friends live at A and C and male friends at B and D. If Z 5 the number of visits to female friends, what is the pmf of Z? Calculate the following probabilities directly from the cdf: a. p(2), that is, P(X 5 2) b. P(X . 3) c. P(2 # X # 5) d. P(2 , X , 5) 24. An insurance company offers its policyholders a number of different premium payment options. For a randomly selected policyholder, let X 5 the number of months between successive payments. The cdf of X is as follows: 0 x,1 .30 1 # x , .40 3 # x , F(x) 5 f .45 4 # x , .60 6 # x , 1 12 # x B 27. After all students have left the classroom, a statistics professor notices that four copies of the text were left under desks. At the beginning of the next lecture, the professor distributes the four books in a completely random fashion to each of the four students (1, 2, 3, and 4) who claim to have left books. One possible outcome is that 1 receives 2’s book, 2 receives 4’s book, 3 receives his or her own book, and 4 receives 1’s book. This outcome can be abbreviated as (2, 4, 3, 1). a. List the other 23 possible outcomes. b. Let X denote the number of students who receive their own book. Determine the pmf of X. 3 4 6 12 a. What is the pmf of X? b. Using just the cdf, compute P(3 # X # 6) and P(4 # X). 25. In Example 3.12, let Y 5 the number of girls born before the experiment terminates. With p 5 P(B) and 1 2 p 5 P(G), what is the pmf of Y? [Hint: First list the possible values of Y, starting with the smallest, and proceed until you see a general formula.] 28. Show that the cdf F(x) is a nondecreasing function; that is, x1 , x2 implies that F(x1) # F(x2). Under what condition will F(x1) 5 F(x2)? 3.3 Expected Values Consider a university having 15,000 students and let X 5 the number of courses for which a randomly selected student is registered. The pmf of X follows. Since p(1) 5 .01, we know that (.01) # (15,000) 5 150of the students are registered for one course, and similarly for the other x values. x 1 2 3 4 5 6 7 p(x) .01 .03 .13 .25 .39 .17 .02 Number registered 150 450 1950 3750 5850 2550 300 (3.6) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.3. Expected Values 107 The average number of courses per student, or the average value of X in the population, results from computing the total number of courses taken by all students and dividing by the total number of students. Since each of 150 students is taking one course, these 150 contribute 150 courses to the total. Similarly, 450 students contribute 2(450) courses, and so on. The population average value of X is then 1(150) 1 2(450) 1 3(1950) 1 c 1 7(300) 5 4.57 15,000 (3.7) Since 150/15,000 5 .01 5 p(1), 450/15,000 5 .03 5 p(2), and so on, an alternative expression for (3.7) is 1 # p(1) 1 2 # p(2) 1 c 1 7 # p(7) (3.8) Expression (3.8) shows that to compute the population average value of X, we need only the possible values of X along with their probabilities (proportions). In particular, the population size is irrelevant as long as the pmf is given by (3.6). The average or mean value of X is then a weighted average of the possible values 1, . . . , 7, where the weights are the probabilities of those values. The Expected Value of X DEFINITION Let X be a discrete rv with set of possible values D and pmf p(x). The expected value or mean value of X, denoted by E(X) or mX or just m, is E(X) 5 mX 5 g x # p(x) x僆D Example 3.16 For the pmf of X 5 number of courses in (3.6), m 5 1 # p(1) 1 2 # p(2) 1 c 1 7 # p(7) 5 (1)(.01) 1 2(.03) 1 c 1 (7)(.02) 5 .01 1 .06 1 .39 1 1.00 1 1.95 1 1.02 1 .14 5 4.57 If we think of the population as consisting of the X values 1, 2, . . . , 7, then m 5 4.57 is the population mean. In the sequel, we will often refer to m as the population mean rather than the mean of X in the population. Notice that m here is not 4, the ordinary average of 1, . . . , 7, because the distribution puts more weight on 4, 5, and 6 than on other X values. ■ In Example 3.16, the expected value m was 4.57, which is not a possible value of X. The word expected should be interpreted with caution because one would not expect to see an X value of 4.57 when a single student is selected. Example 3.17 Just after birth, each newborn child is rated on a scale called the Apgar scale. The possible ratings are 0, 1, . . . , 10, with the child’s rating determined by color, muscle tone, respiratory effort, heartbeat, and reflex irritability (the best possible score is 10). Let X be the Apgar score of a randomly selected child born at a certain hospital during the next year, and suppose that the pmf of X is x p(x) 0 1 2 3 4 5 6 7 8 9 10 .002 .001 .002 .005 .02 .04 .18 .37 .25 .12 .01 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 108 CHAPTER 3 Discrete Random Variables and Probability Distributions Then the mean value of X is E(X) 5 m 5 0(.002) 1 1(.001) 1 2(.002) 1 c 1 8(.25) 1 9(.12) 1 10(.01) 5 7.15 Again, m is not a possible value of the variable X. Also, because the variable relates to a future child, there is no concrete existing population to which m refers. Instead, we think of the pmf as a model for a conceptual population consisting of the values 0, 1, 2, . . . , 10. The mean value of this conceptual population is then ■ m 5 7.15. Example 3.18 Let X 5 1 if a randomly selected vehicle passes an emissions test and X 5 0 otherwise. Then X is a Bernoulli rv with pmf p(1) 5 p and p(0) 5 1 2 p, from which E(X) 5 0 # p(0) 1 1 # p(1) 5 0(1 2 p) 1 1(p) 5 p. That is, the expected value of X is just the probability that X takes on the value 1. If we conceptualize a population consisting of 0s in proportion 1 2 p and 1s in proportion p, then the population average is m 5 p. ■ Example 3.19 The general form for the pmf of X 5 number of children born up to and including the first boy is p(x) 5 e p(1 2 p)x21 x 5 1, 2, 3, . . . 0 otherwise From the definition, E(X) 5 ` ` x51 x51 g x # p(x) 5 g xp(1 2 p)x21 5 p g c 2 D d (1 2 p)x d dp (3.9) If we interchange the order of taking the derivative and the summation, the sum is that of a geometric series. After the sum is computed, the derivative is taken, and the final result is E(X) 5 1/p. If p is near 1, we expect to see a boy very soon, whereas if p is near 0, we expect many births before the first boy. For p 5 .5, ■ E(X) 5 2. There is another frequently used interpretation of m. Consider observing a first value x1 of X, then a second value x2, a third value x3, and so on. After doing this a large number of times, calculate the sample average of the observed x'i s. This average will typically be quite close to m. That is, m can be interpreted as the long-run average observed value of X when the experiment is performed repeatedly. In Example 3.17, the long-run average Apgar score is m 5 7.15. Example 3.20 Let X, the number of interviews a student has prior to getting a job, have pmf p(x) 5 e k/x 2 x 5 1, 2, 3, . . . 0 otherwise ` where k is chosen so that g x51 (k/x 2) 5 1. (In a mathematics course on infinite ` 2 series, it is shown that g x51 (1/x ) , ` , which implies that such a k exists, but its exact value need not concern us.) The expected value of X is ` m 5 E(X) 5 gx x51 # ` k 1 5 kg 2 x x51 x (3.10) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.3. Expected Values 109 The sum on the right of Equation (3.10) is the famous harmonic series of mathematics and can be shown to equal ⬁. E(X) is not finite here because p(x) does not decrease sufficiently fast as x increases; statisticians say that the probability distribution of X has “a heavy tail.” If a sequence of X values is chosen using this distribution, the sample average will not settle down to some finite number but will tend to grow without bound. Statisticians use the phrase “heavy tails” in connection with any distribution having a large amount of probability far from m (so heavy tails do not require m 5 ` ). Such heavy tails make it difficult to make inferences about m. ■ The Expected Value of a Function Sometimes interest will focus on the expected value of some function h(X) rather than on just E(X). Example 3.21 Suppose a bookstore purchases ten copies of a book at $6.00 each to sell at $12.00 with the understanding that at the end of a 3-month period any unsold copies can be redeemed for $2.00. If X 5 the number of copies sold, then net revenue 5 h(X) 5 12X 1 2(10 2 X) 2 60 5 10X 2 40. What then is the expected net revenue? ■ An easy way of computing the expected value of h(X) is suggested by the following example. Example 3.22 The cost of a certain vehicle diagnostic test depends on the number of cylinders X in the vehicle’s engine. Suppose the cost function is given by h(X) 5 20 1 3X 1 .5X 2. Since X is a random variable, so is Y 5 h(X). The pmf of X and derived pmf of Y are as follows: x 4 6 8 y 40 56 76 p(y) .5 .3 .2 1 p(x) .5 .3 .2 With D* denoting possible values of Y, E(Y) 5 E[h(X)] 5 g y # p(y) D* 5 (40)(.5) 1 (56)(.3) 1 (76)(.2) 5 h(4) # (.5) 1 h(6) # (.3) 1 h(8) # (.2) 5 (3.11) g h(x) # p(x) D According to Equation (3.11), it was not necessary to determine the pmf of Y to obtain E(Y); instead, the desired expected value is a weighted average of the possible h(x) (rather than x) values. ■ PROPOSITION If the rv X has a set of possible values D and pmf p(x), then the expected value of any function h(X), denoted by E[h(X)] or mh(X), is computed by E[h(X)] 5 g h(x) # p(x) D Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 110 CHAPTER 3 Discrete Random Variables and Probability Distributions That is, E[h(X)] is computed in the same way that E(X) itself is, except that h(x) is substituted in place of x. Example 3.23 A computer store has purchased three computers of a certain type at $500 apiece. It will sell them for $1000 apiece. The manufacturer has agreed to repurchase any computers still unsold after a specified period at $200 apiece. Let X denote the number of computers sold, and suppose that p(0) 5 .1, p(1) 5 .2, p(2) 5 .3, and p(3) 5 .4. With h(X) denoting the profit associated with selling X units, the given information implies that h(X) 5 revenue 2 cost 5 1000X 1 200(3 2 X) 2 1500 5 800X 2 900. The expected profit is then E[h(X)] 5 h(0) # p(0) 1 h(1) # p(1) 1 h(2) # p(2) 1 h(3) # p(3) 5 (2900)(.1) 1 (2100)(.2) 1 (700)(.3) 1 (1500)(.4) 5 $700 ■ Rules of Expected Value The h(X) function of interest is quite frequently a linear function aX 1 b. In this case, E[h(X)] is easily computed from E(X). E(aX 1 b) 5 a # E(X) 1 b PROPOSITION (Or, using alternative notation, maX1b 5 a # mX 1 b) To paraphrase, the expected value of a linear function equals the linear function evaluated at the expected value E(X). Since h(X) in Example 3.23 is linear and E(X) 5 2, E[h(x)] 5 800(2) 2 900 5 $700, as before. Proof E(aX 1 b) 5 g (ax 1 b) # p(x) 5 a g x # p(x) 1 b g p(x) D D D ■ 5 aE(X) 1 b Two special cases of the proposition yield two important rules of expected value. 1. For any constant a, E(aX) 5 a # E(X) (take b 5 0). 2. For any constant b, E(X 1 b) 5 E(X) 1 b (take a 5 1). (3.12) Multiplication of X by a constant a typically changes the unit of measurement, for example, from inches to cm, where a 5 2.54. Rule 1 says that the expected value in the new units equals the expected value in the old units multiplied by the conversion factor a. Similarly, if a constant b is added to each possible value of X, then the expected value will be shifted by that same constant amount. The Variance of X The expected value of X describes where the probability distribution is centered. Using the physical analogy of placing point mass p(x) at the value x on a onedimensional axis, if the axis were then supported by a fulcrum placed at m, there would be no tendency for the axis to tilt. This is illustrated for two different distributions in Figure 3.7. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.3. Expected Values p(x) p(x) .5 .5 1 2 3 (a) Figure 3.7 5 1 2 3 5 6 7 111 8 (b) Two different probability distributions with m 5 4 Although both distributions pictured in Figure 3.7 have the same center m, the distribution of Figure 3.7(b) has greater spread or variability or dispersion than does that of Figure 3.7(a). We will use the variance of X to assess the amount of variability in (the distribution of ) X, just as s2 was used in Chapter 1 to measure variability in a sample. DEFINITION Let X have pmf p(x) and expected value m. Then the variance of X, denoted by V(X) or s2X, or just s2, is V(X) 5 g (x 2 m)2 # p(x) 5 E[(X 2 m)2] D The standard deviation (SD) of X is sX 5 #s2X The quantity h(X) 5 (X 2 m)2 is the squared deviation of X from its mean, and s2 is the expected squared deviation—i.e., the weighted average of squared deviations, where the weights are probabilities from the distribution. If most of the probability distribution is close to m, then s2 will be relatively small. However, if there are x values far from m that have large p(x), then s2 will be quite large. Very roughly, s can be interpreted as the size of a representative deviation from the mean value m. So if s 5 10, then in a long sequence of observed X values, some will deviate from m by more than 10 while others will be closer to the mean than that—a typical deviation from the mean will be something on the order of 10. Example 3.24 A library has an upper limit of 6 on the number of videos that can be checked out to an individual at one time. Consider only those who check out videos, and let X denote the number of videos checked out to a randomly selected individual. The pmf of X is as follows: x p(x) 1 2 3 4 5 6 .30 .25 .15 .05 .10 .15 The expected value of X is easily seen to be m 5 2.85. The variance of X is then 6 V(X) 5 s2 5 g (x 2 2.85)2 # p(x) x51 5 (1 2 2.85)2(.30) 1 (2 2 2.85)2(.25) 1 c 1 (6 2 2.85)2(.15) 5 3.2275 The standard deviation of X is s 5 13.2275 5 1.800. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 112 CHAPTER 3 Discrete Random Variables and Probability Distributions When the pmf p(x) specifies a mathematical model for the distribution of population values, both s2 and s measure the spread of values in the population; s2 is the population variance, and s is the population standard deviation. A Shortcut Formula for S2 The number of arithmetic operations necessary to compute s2 can be reduced by using an alternative formula. V(X) 5 s2 5 c g x 2 # p(x)d 2 m2 5 E(X 2) 2 [E(X)]2 PROPOSITION D In using this formula, E(X2) is computed first without any subtraction; then E(X) is computed, squared, and subtracted (once) from E(X2). Example 3.25 (Example 3.24 continued) The pmf of the number X of videos checked out was given as p(1) 5 .30, p(2) 5 .25, p(3) 5 .15, p(4) 5 .05, p(5) 5 .10, and p(6) 5 .15, from which m 5 2.85 and 6 E(X 2) 5 g x 2 # p(x) 5 (12)(.30) 1 (22)(.25) 1 c 1 (62)(.15) 5 11.35 x51 Thus s 5 11.35 2 (2.85)2 5 3.2275 as obtained previously from the definition. ■ 2 Proof of the Shortcut Formula Expand (x 2 m)2 in the definition of s2 to obtain x 2 2 2mx 1 m2, and then carry g through to each of the three terms: s2 5 g x 2 # p(x) 2 2m # g x # p(x) 1 m2 g p(x) D D D 5 E(X 2) 2 2m # m 1 m2 5 E(X 2) 2 m2 ■ Rules of Variance The variance of h(X) is the expected value of the squared difference between h(X) and its expected value: V[h(X)] 5 s2h(X) 5 g 5h(x) 2 E[h(X)]6 2 # p(x) (3.13) D When h(X) 5 aX 1 b, a linear function, h(x) 2 E[h(X)] 5 ax 1 b 2 (am 1 b) 5 a(x 2 m) Substituting this into (3.13) gives a simple relationship between V[h(X)] and V(X): PROPOSITION V(aX 1 b) 5 s2aX1b 5 a 2 # s2X and saX1b 5 u a u # sx In particular, saX 5 u a u # sX, sX1b 5 sX (3.14) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.3. Expected Values 113 The absolute value is necessary because a might be negative, yet a standard deviation cannot be. Usually multiplication by a corresponds to a change in the unit of measurement (e.g., kg to lb or dollars to euros). According to the first relation in (3.14), the sd in the new unit is the original sd multiplied by the conversion factor. The second relation says that adding or subtracting a constant does not impact variability; it just rigidly shifts the distribution to the right or left. Example 3.26 In the computer sales scenario of Example 3.23, E(X) 5 2 and E(X 2) 5 (0)2(.1) 1 (1)2(.2) 1 (2)2(.3) 1 (3)2(.4) 5 5 so V(X) 5 5 2 (2)2 5 1. The profit function h(X) 5 800X 2 900 then has variance (800)2 # V(X) 5 (640,000)(1) 5 640,000and standard deviation 800. ■ EXERCISES Section 3.3 (29–45) 29. The pmf of the amount of memory X (GB) in a purchased flash drive was given in Example 3.13 as x p(x) 1 2 4 8 16 .05 .10 .35 .40 .10 Compute the following: a. E(X) b. V(X) directly from the definition c. The standard deviation of X d. V(X) using the shortcut formula 30. An individual who has automobile insurance from a certain company is randomly selected. Let Y be the number of moving violations for which the individual was cited during the last 3 years. The pmf of Y is y p(y) 0 1 2 3 .60 .25 .10 .05 a. Compute E(Y). b. Suppose an individual with Y violations incurs a surcharge of $100Y2. Calculate the expected amount of the surcharge. 31. Refer to Exercise 12 and calculate V(Y) and sY. Then determine the probability that Y is within 1 standard deviation of its mean value. 32. An appliance dealer sells three different models of upright freezers having 13.5, 15.9, and 19.1 cubic feet of storage space, respectively. Let X 5 the amount of storage space purchased by the next customer to buy a freezer. Suppose that X has pmf x p(x) 13.5 15.9 19.1 .2 .5 .3 a. Compute E(X), E(X2), and V(X). b. If the price of a freezer having capacity X cubic feet is 25X 2 8.5, what is the expected price paid by the next customer to buy a freezer? c. What is the variance of the price 25X 2 8.5 paid by the next customer? d. Suppose that although the rated capacity of a freezer is X, the actual capacity is h(X) 5 X 2 .01X 2. What is the expected actual capacity of the freezer purchased by the next customer? 33. Let X be a Bernoulli rv with pmf as in Example 3.18. a. Compute E(X2). b. Show that V(X) 5 p(1 2 p). c. Compute E(X79). 34. Suppose that the number of plants of a particular type found in a rectangular sampling region (called a quadrat by ecologists) in a certain geographic area is an rv X with pmf p(x) 5 e c/x 3 x 5 1, 2, 3, . . . 0 otherwise Is E(X) finite? Justify your answer (this is another distribution that statisticians would call heavy-tailed). 35. A small market orders copies of a certain magazine for its magazine rack each week. Let X 5 demand for the magazine, with pmf x 1 2 3 4 5 6 p(x) 1 15 2 15 3 15 4 15 3 15 2 15 Suppose the store owner actually pays $2.00 for each copy of the magazine and the price to customers is $4.00. If magazines left at the end of the week have no salvage value, is it better to order three or four copies of the magazine? [Hint: For both three and four copies ordered, express net revenue as a function of demand X, and then compute the expected revenue.] Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 114 CHAPTER 3 Discrete Random Variables and Probability Distributions 36. Let X be the damage incurred (in $) in a certain type of accident during a given year. Possible X values are 0, 1000, 5000, and 10000, with probabilities .8, .1, .08, and .02, respectively. A particular company offers a $500 deductible policy. If the company wishes its expected profit to be $100, what premium amount should it charge? 40. a. Draw a line graph of the pmf of X in Exercise 35. Then determine the pmf of 2X and draw its line graph. From these two pictures, what can you say about V(X) and V(2X)? b. Use the proposition involving V(aX 1 b) to establish a general relationship between V(X) and V(2X). 37. The n candidates for a job have been ranked 1, 2, 3, . . . , n. Let X 5 the rank of a randomly selected candidate, so that X has pmf 41. Use the definition in Expression (3.13) to prove that V(aX 1 b) 5 a 2 # s2X. [Hint: With h(X) 5 aX 1 b, E[h(X)] 5 am 1 b where m 5 E(X).] p(x) 5 e 1/n x 5 1, 2, 3, . . . , n 0 otherwise (this is called the discrete uniform distribution). Compute E(X) and V(X) using the shortcut formula. [Hint: The sum of the first n positive integers is n(n 1 1)/2, whereas the sum of their squares is n(n 1 1)(2n 1 1)/6.] 38. Let X 5 the outcome when a fair die is rolled once. If before the die is rolled you are offered either (1/3.5) dollars or h(X) 5 1/X dollars, would you accept the guaranteed amount or would you gamble? [Note: It is not generally true that 1/E(X) 5 E(1/X).] 39. A chemical supply company currently has in stock 100 lb of a certain chemical, which it sells to customers in 5-lb batches. Let X 5 the number of batches ordered by a randomly chosen customer, and suppose that X has pmf x 1 2 3 4 p(x) .2 .4 .3 .1 Compute E(X) and V(X). Then compute the expected number of pounds left after the next customer’s order is shipped and the variance of the number of pounds left. [Hint: The number of pounds left is a linear function of X.] 42. Suppose E(X) 5 5 and E[X(X 2 1)] 5 27.5. What is a. E(X2)? [Hint: E[X(X 2 1)] 5 E[X 2 2 X] 5 E(X 2) 2 E(X)]? b. V(X)? c. The general relationship among the quantities E(X), E[X(X 2 1)], and V(X)? 43. Write a general rule for E(X 2 c) where c is a constant. What happens when you let c 5 m, the expected value of X? 44. A result called Chebyshev’s inequality states that for any probability distribution of an rv X and any number k that is at least 1, P(u X 2 m u $ ks) # 1/k2. In words, the probability that the value of X lies at least k standard deviations from its mean is at most 1/k2. a. What is the value of the upper bound for k 5 2? k 5 3? k 5 4? k 5 5? k 5 10? b. Compute m and s for the distribution of Exercise 13. Then evaluate P(u X 2 m u $ ks) for the values of k given in part (a). What does this suggest about the upper bound relative to the corresponding probability? c. Let X have possible values 21, 0, and 1, with probabilities 1 8 , , and 1 , respectively. What is P(u X 2 m u $ 3s), 18 9 18 and how does it compare to the corresponding bound? d. Give a distribution for which P(u X 2 m u $ 5s) 5 .04. 45. If a # X # b, show that a # E(X) # b. 3.4 The Binomial Probability Distribution There are many experiments that conform either exactly or approximately to the following list of requirements: 1. The experiment consists of a sequence of n smaller experiments called trials, where n is fixed in advance of the experiment. 2. Each trial can result in one of the same two possible outcomes (dichotomous trials), which we generically denote by success (S) and failure (F). 3. The trials are independent, so that the outcome on any particular trial does not influence the outcome on any other trial. 4. The probability of success P(S) is constant from trial to trial; we denote this probability by p. DEFINITION An experiment for which Conditions 1–4 are satisfied is called a binomial experiment. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.4. The Binomial Probability Distribution Example 3.27 115 The same coin is tossed successively and independently n times. We arbitrarily use S to denote the outcome H (heads) and F to denote the outcome T (tails). Then this experiment satisfies Conditions 1–4. Tossing a thumbtack n times, with ■ S 5 point up and F 5 point down , also results in a binomial experiment. Many experiments involve a sequence of independent trials for which there are more than two possible outcomes on any one trial. A binomial experiment can then be created by dividing the possible outcomes into two groups. Example 3.28 The color of pea seeds is determined by a single genetic locus. If the two alleles at this locus are AA or Aa (the genotype), then the pea will be yellow (the phenotype), and if the allele is aa, the pea will be green. Suppose we pair off 20 Aa seeds and cross the two seeds in each of the ten pairs to obtain ten new genotypes. Call each new genotype a success S if it is aa and a failure otherwise. Then with this identification of S and F, the experiment is binomial with n 5 10 and p 5 P(aa genotype). If each member of the pair is equally likely to contribute a or A, then p 5 P(a) # P(a) 5 Q 12 R Q 12 R 5 14. ■ Example 3.29 Suppose a certain city has 50 licensed restaurants, of which 15 currently have at least one serious health code violation and the other 35 have no serious violations. There are five inspectors, each of whom will inspect one restaurant during the coming week. The name of each restaurant is written on a different slip of paper, and after the slips are thoroughly mixed, each inspector in turn draws one of the slips without replacement. Label the ith trial as a success if the ith restaurant selected (i 5 1, . . . , 5) has no serious violations. Then P(S on first trial) 5 35 5 .70 50 and P(S on second trial) 5 P(SS) 1 P(FS) 5 P(second S | first S)P(first S) 1 P(second S | first F)P(first F) 34 # 35 35 # 15 35 34 15 35 5 1 5 a 1 b 5 5 .70 49 50 49 50 50 49 49 50 Similarly, it can be shown that P(S on ith trial) 5 .70 for i 5 3, 4, 5. However, P(S on fifth trial u SSSS) 5 31 5 .67 46 P(S on fifth trialu FFFF) 5 35 5 .76 46 whereas The experiment is not binomial because the trials are not independent. In general, if sampling is without replacement, the experiment will not yield independent trials. If each slip had been replaced after being drawn, then trials would have been independent, but this might have resulted in the same restaurant being inspected by more than one inspector. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 116 CHAPTER 3 Discrete Random Variables and Probability Distributions Example 3.30 A certain state has 500,000 licensed drivers, of whom 400,000 are insured. A sample of 10 drivers is chosen without replacement. The ith trial is labeled S if the ith driver chosen is insured. Although this situation would seem identical to that of Example 3.29, the important difference is that the size of the population being sampled is very large relative to the sample size. In this case P(S on 2 | S on 1) 5 399,999 5 .80000 499,999 and P(S on 10 | S on first 9) 5 399,991 5 .799996 < .80000 499,991 These calculations suggest that although the trials are not exactly independent, the conditional probabilities differ so slightly from one another that for practical purposes the trials can be regarded as independent with constant P(S) 5 .8. Thus, to a very good approximation, the experiment is binomial with n 5 10 and p 5 .8. ■ We will use the following rule of thumb in deciding whether a “withoutreplacement” experiment can be treated as a binomial experiment. RULE Consider sampling without replacement from a dichotomous population of size N. If the sample size (number of trials) n is at most 5% of the population size, the experiment can be analyzed as though it were exactly a binomial experiment. By “analyzed,” we mean that probabilities based on the binomial experiment assumptions will be quite close to the actual “without-replacement” probabilities, which are typically more difficult to calculate. In Example 3.29, n/N 5 5/50 5 .1 . .05, so the binomial experiment is not a good approximation, but in Example 3.30, n/N 5 10/500,000 , .05. The Binomial Random Variable and Distribution In most binomial experiments, it is the total number of S’s, rather than knowledge of exactly which trials yielded S’s, that is of interest. DEFINITION The binomial random variable X associated with a binomial experiment consisting of n trials is defined as X 5 the number of S’s among the n trials Suppose, for example, that n 5 3. Then there are eight possible outcomes for the experiment: SSS SSF SFS SFF FSS FSF FFS FFF From the definition of X, X(SSF) 5 2, X(SFF) 5 1, and so on. Possible values for X in an n-trial experiment are x 5 0, 1, 2, . . . , n. We will often write X | Bin(n, p) to indicate that X is a binomial rv based on n trials with success probability p. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 117 3.4. The Binomial Probability Distribution NOTATION Because the pmf of a binomial rv X depends on the two parameters n and p, we denote the pmf by b(x; n, p). Consider first the case n 5 4 for which each outcome, its probability, and corresponding x value are listed in Table 3.1. For example, P(SSFS) 5 P(S) # P(S) # P(F) # P(S) (independent trials) 5 p # p # (1 2 p) # p (constant P(S)) 5 p3 # (1 2 p) Table 3.1 Outcomes and Probabilities for a Binomial Experiment with Four Trials Outcome x SSSS SSSF SSFS SSFF SFSS SFSF SFFS SFFF 4 3 3 2 3 2 2 1 Probability p4 p3(1 2 p3(1 2 p2(1 2 p3(1 2 p2(1 2 p2(1 2 p(1 2 Outcome x FSSS FSSF FSFS FSFF FFSS FFSF FFFS FFFF 3 2 2 1 2 1 1 0 p) p) p)2 p) p)2 p)2 p)3 Probability p3(1 p2(1 p2(1 p(1 p2(1 p(1 p(1 (1 2 2 2 2 2 2 2 2 p) p)2 p)2 p)3 p)2 p)3 p)3 p)4 In this special case, we wish b(x; 4, p) for x 5 0, 1, 2, 3, and 4. For b(3; 4, p), let’s identify which of the 16 outcomes yield an x value of 3 and sum the probabilities associated with each such outcome: b(3; 4, p) 5 P(FSSS) 1 P(SFSS) 1 P(SSFS) 1 P(SSSF) 5 4p3(1 2 p) There are four outcomes with X 5 3 and each has probability p3(1 2 p) (the order of S’s and F’s is not important, but only the number of S’s), so b(3; 4, p) 5 e number of outcomes f with X 5 3 # e probability of any particular f outcome with X 5 3 Similarly, b(2; 4, p) 5 6p2(1 2 p)2, which is also the product of the number of outcomes with X 5 2 and the probability of any such outcome. In general, b(x; n, p) 5 e number of sequences of f length n consisting of x S’s # e probability of any f particular such sequence Since the ordering of S’s and F’s is not important, the second factor in the previous equation is px(1 2 p)n2x (e.g., the first x trials resulting in S and the last n 2 x resulting in F ). The first factor is the number of ways of choosing x of the n trials to be S’s—that is, the number of combinations of size x that can be constructed from n distinct objects (trials here). THEOREM b(x; n, p) 5 u n Q x R px(1 2 p)n2x x 5 0, 1, 2, . . . , n 0 otherwise Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 118 CHAPTER 3 Discrete Random Variables and Probability Distributions Example 3.31 Each of six randomly selected cola drinkers is given a glass containing cola S and one containing cola F. The glasses are identical in appearance except for a code on the bottom to identify the cola. Suppose there is actually no tendency among cola drinkers to prefer one cola to the other. Then p 5 P(a selected individual prefers S) 5 .5, so with X 5 the number among the six who prefer S, X | Bin(6,.5). Thus 6 P(X 5 3) 5 b(3; 6, .5) 5 a b(.5)3(.5)3 5 20(.5)6 5 .313 3 The probability that at least three prefer S is 6 P(3 # X) 5 6 g b(x; 6, .5) 5 g a 6x b(.5)x(.5)62x 5 .656 x53 x53 and the probability that at most one prefers S is 1 P(X # 1) 5 g b(x; 6, .5) 5 .109 ■ x50 Using Binomial Tables* Even for a relatively small value of n, the computation of binomial probabilities can be tedious. Appendix Table A.1 tabulates the cdf F(x) 5 P(X # x) for n 5 5, 10, 15, 20, 25 in combination with selected values of p. Various other probabilities can then be calculated using the proposition on cdf’s from Section 3.2. A table entry of 0 signifies only that the probability is 0 to three significant digits since all table entries are actually positive. NOTATION For X | Bin(n, p), the cdf will be denoted by x B(x; n, p) 5 P(X # x) 5 g b(y; n, p) x 5 0, 1, . . . , n y50 Example 3.32 Suppose that 20% of all copies of a particular textbook fail a certain binding strength test. Let X denote the number among 15 randomly selected copies that fail the test. Then X has a binomial distribution with n 5 15 and p 5 .2. 1. The probability that at most 8 fail the test is 8 P(X # 8) 5 g b(y; 15, .2) 5 B(8; 15, .2) y50 which is the entry in the x 5 8 row and the p 5 .2 column of the n 5 15 binomial table. From Appendix Table A.1, the probability is B(8; 15, .2) 5 .999. 2. The probability that exactly 8 fail is P(X 5 8) 5 P(X # 8) 2 P(X # 7) 5 B(8; 15, .2) 2 B(7; 15, .2) which is the difference between two consecutive entries in the p 5 .2 column. The result is .999 2 .996 5 .003. * Statistical software packages such as Minitab and R will provide the pmf or cdf almost instantaneously upon request for any value of p and n ranging from 2 up into the millions. There is also an R command for calculating the probability that X lies in some interval. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.4. The Binomial Probability Distribution 119 3. The probability that at least 8 fail is P(X $ 8) 5 1 2 P(X # 7) 5 1 2 B(7; 15, .2) entry in x 5 7 b row of p 5 .2 column 5 1 2 .996 5 .004 512 a 4. Finally, the probability that between 4 and 7, inclusive, fail is P(4 # X # 7) 5 P(X 5 4, 5, 6, or 7) 5 P(X # 7) 2 P(X # 3) 5 B(7; 15, .2) 2 B(3; 15, .2) 5 .996 2 .648 5 .348 Notice that this latter probability is the difference between entries in the x 5 7 and x 5 3 rows, not the x 5 7 and x 5 4 rows. ■ Example 3.33 An electronics manufacturer claims that at most 10% of its power supply units need service during the warranty period. To investigate this claim, technicians at a testing laboratory purchase 20 units and subject each one to accelerated testing to simulate use during the warranty period. Let p denote the probability that a power supply unit needs repair during the period (the proportion of all such units that need repair). The laboratory technicians must decide whether the data resulting from the experiment supports the claim that p # .10. Let X denote the number among the 20 sampled that need repair, so X , Bin(20, p). Consider the decision rule: Reject the claim that p # .10 in favor of the conclusion that p . .10 if x $ 5 (where x is the observed value of X), and consider the claim plausible if x # 4. The probability that the claim is rejected when p 5 .10 (an incorrect conclusion) is P(X $ 5 when p 5 .10) 5 1 2 B(4; 20, .1) 5 1 2 .957 5 .043 The probability that the claim is not rejected when p 5 .20 (a different type of incorrect conclusion) is P(X # 4 when p 5 .2) 5 B(4; 20, .2) 5 .630 The first probability is rather small, but the second is intolerably large. When p 5 .20, so that the manufacturer has grossly understated the percentage of units that need service, and the stated decision rule is used, 63% of all samples will result in the manufacturer’s claim being judged plausible! One might think that the probability of this second type of erroneous conclusion could be made smaller by changing the cutoff value 5 in the decision rule to something else. However, although replacing 5 by a smaller number would yield a probability smaller than .630, the other probability would then increase. The only way to make both “error probabilities” small is to base the decision rule on an experiment involving many more units. ■ The Mean and Variance of X For n 5 1, the binomial distribution becomes the Bernoulli distribution. From Example 3.18, the mean value of a Bernoulli variable is m 5 p, so the expected number of S’s on any single trial is p. Since a binomial experiment consists of n trials, intuition suggests that for X , Bin(n, p), E(X) 5 np, the product of the number of trials and the probability of success on a single trial. The expression for V(X) is not so intuitive. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 120 Discrete Random Variables and Probability Distributions CHAPTER 3 PROPOSITION If X , Bin(n, p), then E(X) 5 np, sX 5 1npq (where q 5 1 2 p). V(X) 5 np(1 2 p) 5 npq, and Thus, calculating the mean and variance of a binomial rv does not necessitate evaluating summations. The proof of the result for E(X) is sketched in Exercise 64. Example 3.34 If 75% of all purchases at a certain store are made with a credit card and X is the number among ten randomly selected purchases made with a credit card, then X , Bin(10, .75). Thus E(X) 5 np 5 (10)(.75) 5 7.5, V(X) 5 npq 5 10(.75)(.25) 5 1.875, and s 5 11.875 5 1.37. Again, even though X can take on only integer values, E(X) need not be an integer. If we perform a large number of independent binomial experiments, each with n 5 10 trials and p 5 .75, then the average number of S’s per experiment will be close to 7.5. The probability that X is within 1 standard deviation of its mean value is P(7.5 2 1.37 # X # 7.5 1 1.37) 5 P(6.13 # X # 8.87) 5 P(X 5 7 or 8) 5 .532 . ■ EXERCISES Section 3.4 (46–67) 46. Compute the following binomial probabilities directly from the formula for b(x; n, p): a. b(3; 8, .35) b. b(5; 8, .6) c. P(3 # X # 5) when n 5 7 and p 5 .6 d. P(1 # X) when n 5 9 and p 5 .1 47. Use Appendix Table A.1 to obtain the following probabilities: a. B(4; 15, .3) b. b(4; 15, .3) c. b(6; 15, .7) d. P(2 # X # 4) when X , Bin(15, .3) e. P(2 # X) when X , Bin(15, .3) f. P(X # 1) when X , Bin(15, .7) g. P(2 , X , 6) when X , Bin(15, .3) 48. When circuit boards used in the manufacture of compact disc players are tested, the long-run percentage of defectives is 5%. Let X 5 the number of defective boards in a random sample of size n 5 25, so X , Bin(25, .05). a. Determine P(X # 2). b. Determine P(X $ 5). c. Determine P(1 # X # 4). d. What is the probability that none of the 25 boards is defective? e. Calculate the expected value and standard deviation of X. 49. A company that produces fine crystal knows from experience that 10% of its goblets have cosmetic flaws and must be classified as “seconds.” a. Among six randomly selected goblets, how likely is it that only one is a second? b. Among six randomly selected goblets, what is the probability that at least two are seconds? c. If goblets are examined one by one, what is the probability that at most five must be selected to find four that are not seconds? 50. A particular telephone number is used to receive both voice calls and fax messages. Suppose that 25% of the incoming calls involve fax messages, and consider a sample of 25 incoming calls. What is the probability that a. At most 6 of the calls involve a fax message? b. Exactly 6 of the calls involve a fax message? c. At least 6 of the calls involve a fax message? d. More than 6 of the calls involve a fax message? 51. Refer to the previous exercise. a. What is the expected number of calls among the 25 that involve a fax message? b. What is the standard deviation of the number among the 25 calls that involve a fax message? c. What is the probability that the number of calls among the 25 that involve a fax transmission exceeds the expected number by more than 2 standard deviations? 52. Suppose that 30% of all students who have to buy a text for a particular course want a new copy (the successes!), whereas the other 70% want a used copy. Consider randomly selecting 25 purchasers. a. What are the mean value and standard deviation of the number who want a new copy of the book? b. What is the probability that the number who want new copies is more than two standard deviations away from the mean value? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.4. The Binomial Probability Distribution c. The bookstore has 15 new copies and 15 used copies in stock. If 25 people come in one by one to purchase this text, what is the probability that all 25 will get the type of book they want from current stock? [Hint: Let X 5 the number who want a new copy. For what values of X will all 25 get what they want?] d. Suppose that new copies cost $100 and used copies cost $70. Assume the bookstore currently has 50 new copies and 50 used copies. What is the expected value of total revenue from the sale of the next 25 copies purchased? Be sure to indicate what rule of expected value you are using. [Hint: Let h(X) 5 the revenue when X of the 25 purchasers want new copies. Express this as a linear function.] 53. Exercise 30 (Section 3.3) gave the pmf of Y, the number of traffic citations for a randomly selected individual insured by a particular company. What is the probability that among 15 randomly chosen such individuals a. At least 10 have no citations? b. Fewer than half have at least one citation? c. The number that have at least one citation is between 5 and 10, inclusive?* 54. A particular type of tennis racket comes in a midsize version and an oversize version. Sixty percent of all customers at a certain store want the oversize version. a. Among ten randomly selected customers who want this type of racket, what is the probability that at least six want the oversize version? b. Among ten randomly selected customers, what is the probability that the number who want the oversize version is within 1 standard deviation of the mean value? c. The store currently has seven rackets of each version. What is the probability that all of the next ten customers who want this racket can get the version they want from current stock? 55. Twenty percent of all telephones of a certain type are submitted for service while under warranty. Of these, 60% can be repaired, whereas the other 40% must be replaced with new units. If a company purchases ten of these telephones, what is the probability that exactly two will end up being replaced under warranty? 56. The College Board reports that 2% of the 2 million high school students who take the SAT each year receive special accommodations because of documented disabilities (Los Angeles Times, July 16, 2002). Consider a random sample of 25 students who have recently taken the test. a. What is the probability that exactly 1 received a special accommodation? b. What is the probability that at least 1 received a special accommodation? c. What is the probability that at least 2 received a special accommodation? d. What is the probability that the number among the 25 who received a special accommodation is within 2 * “Between a and b, inclusive” is equivalent to (a # X # b). 121 standard deviations of the number you would expect to be accommodated? e. Suppose that a student who does not receive a special accommodation is allowed 3 hours for the exam, whereas an accommodated student is allowed 4.5 hours. What would you expect the average time allowed the 25 selected students to be? 57. Suppose that 90% of all batteries from a certain supplier have acceptable voltages. A certain type of flashlight requires two type-D batteries, and the flashlight will work only if both its batteries have acceptable voltages. Among ten randomly selected flashlights, what is the probability that at least nine will work? What assumptions did you make in the course of answering the question posed? 58. A very large batch of components has arrived at a distributor. The batch can be characterized as acceptable only if the proportion of defective components is at most .10. The distributor decides to randomly select 10 components and to accept the batch only if the number of defective components in the sample is at most 2. a. What is the probability that the batch will be accepted when the actual proportion of defectives is .01? .05? .10? .20? .25? b. Let p denote the actual proportion of defectives in the batch. A graph of P(batch is accepted) as a function of p, with p on the horizontal axis and P(batch is accepted) on the vertical axis, is called the operating characteristic curve for the acceptance sampling plan. Use the results of part (a) to sketch this curve for 0 # p # 1. c. Repeat parts (a) and (b) with “1” replacing “2” in the acceptance sampling plan. d. Repeat parts (a) and (b) with “15” replacing “10” in the acceptance sampling plan. e. Which of the three sampling plans, that of part (a), (c), or (d), appears most satisfactory, and why? 59. An ordinance requiring that a smoke detector be installed in all previously constructed houses has been in effect in a particular city for 1 year. The fire department is concerned that many houses remain without detectors. Let p 5 the true proportion of such houses having detectors, and suppose that a random sample of 25 homes is inspected. If the sample strongly indicates that fewer than 80% of all houses have a detector, the fire department will campaign for a mandatory inspection program. Because of the costliness of the program, the department prefers not to call for such inspections unless sample evidence strongly argues for their necessity. Let X denote the number of homes with detectors among the 25 sampled. Consider rejecting the claim that p $ .8 if x # 15. a. What is the probability that the claim is rejected when the actual value of p is .8? b. What is the probability of not rejecting the claim when p 5 .7? When p 5 .6? c. How do the “error probabilities” of parts (a) and (b) change if the value 15 in the decision rule is replaced by 14? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 122 CHAPTER 3 Discrete Random Variables and Probability Distributions 60. A toll bridge charges $1.00 for passenger cars and $2.50 for other vehicles. Suppose that during daytime hours, 60% of all vehicles are passenger cars. If 25 vehicles cross the bridge during a particular daytime period, what is the resulting expected toll revenue? [Hint: Let X 5 the number of passenger cars; then the toll revenue h(X) is a linear function of X.] 61. A student who is trying to write a paper for a course has a choice of two topics, A and B. If topic A is chosen, the student will order two books through interlibrary loan, whereas if topic B is chosen, the student will order four books. The student believes that a good paper necessitates receiving and using at least half the books ordered for either topic chosen. If the probability that a book ordered through interlibrary loan actually arrives in time is .9 and books arrive independently of one another, which topic should the student choose to maximize the probability of writing a good paper? What if the arrival probability is only .5 instead of .9? 62. a. For fixed n, are there values of p (0 # p # 1) for which V(X) 5 0? Explain why this is so. b. For what value of p is V(X) maximized? [Hint: Either graph V(X) as a function of p or else take a derivative.] 65. Customers at a gas station pay with a credit card (A), debit card (B), or cash (C ). Assume that successive customers make independent choices, with P(A) 5 .5, P(B) 5 .2, and P(C ) 5 .3. a. Among the next 100 customers, what are the mean and variance of the number who pay with a debit card? Explain your reasoning. b. Answer part (a) for the number among the 100 who don’t pay with cash. 66. An airport limousine can accommodate up to four passengers on any one trip. The company will accept a maximum of six reservations for a trip, and a passenger must have a reservation. From previous records, 20% of all those making reservations do not appear for the trip. Answer the following questions, assuming independence wherever appropriate. a. If six reservations are made, what is the probability that at least one individual with a reservation cannot be accommodated on the trip? b. If six reservations are made, what is the expected number of available places when the limousine departs? c. Suppose the probability distribution of the number of reservations made is given in the accompanying table. Number of reservations 3 4 5 6 Probability .1 .2 .3 .4 63. a. Show that b(x; n, 1 2 p) 5 b(n 2 x; n, p). b. Show that B(x; n, 1 2 p) 5 1 2 B(n 2 x 2 1; n, p). [Hint: At most x S’s is equivalent to at least (n 2 x) F’s.] c. What do parts (a) and (b) imply about the necessity of including values of p greater than .5 in Appendix Table A.1? Let X denote the number of passengers on a randomly selected trip. Obtain the probability mass function of X. 64. Show that E(X) 5 np when X is a binomial random variable. [Hint: First express E(X) as a sum with lower limit x 5 1. Then factor out np, let y 5 x 2 1 so that the sum is from y 5 0 to y 5 n 2 1, and show that the sum equals 1.] 67. Refer to Chebyshev’s inequality given in Exercise 44. Calculate P(u X 2 m u $ ks) for k 5 2 and k 5 3 when X , Bin(20, .5), and compare to the corresponding upper bound. Repeat for X , Bin(20, .75). 3.5 Hypergeometric and Negative Binomial Distributions The hypergeometric and negative binomial distributions are both related to the binomial distribution. The binomial distribution is the approximate probability model for sampling without replacement from a finite dichotomous (S–F) population provided the sample size n is small relative to the population size N; the hypergeometric distribution is the exact probability model for the number of S’s in the sample. The binomial rv X is the number of S’s when the number n of trials is fixed, whereas the negative binomial distribution arises from fixing the number of S’s desired and letting the number of trials be random. The Hypergeometric Distribution The assumptions leading to the hypergeometric distribution are as follows: 1. The population or set to be sampled consists of N individuals, objects, or elements (a finite population). Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.5. Hypergeometric and Negative Binomial Distributions 123 2. Each individual can be characterized as a success (S) or a failure (F), and there are M successes in the population. 3. A sample of n individuals is selected without replacement in such a way that each subset of size n is equally likely to be chosen. The random variable of interest is X 5 the number of S’s in the sample. The probability distribution of X depends on the parameters n, M, and N, so we wish to obtain P(X 5 x) 5 h(x; n, M, N). Example 3.35 During a particular period a university’s information technology office received 20 service orders for problems with printers, of which 8 were laser printers and 12 were inkjet models. A sample of 5 of these service orders is to be selected for inclusion in a customer satisfaction survey. Suppose that the 5 are selected in a completely random fashion, so that any particular subset of size 5 has the same chance of being selected as does any other subset. What then is the probability that exactly x (x 5 0, 1, 2, 3, 4, or 5) of the selected service orders were for inkjet printers? Here, the population size is N 5 20, the sample size is n 5 5, and the number of S’s (inkjet 5 S) and F’s in the population are M 5 12 and N 2 M 5 8, respectively. Consider the value x 5 2. Because all outcomes (each consisting of 5 particular orders) are equally likely, P(X 5 2) 5 h(2; 5, 12, 20) 5 number of outcomes having X 5 2 number of possible outcomes The number of possible outcomes in the experiment is the number of ways of selecting 5 from the 20 objects without regard to order—that is, A 205 B . To count the number of outcomes having X 5 2, note that there are A 122 B ways of selecting 2 of the inkjet orders, and for each such way there are A 83 B ways of selecting the 3 laser orders to fill out the sample. The product rule from Chapter 2 then gives A 122 BA 83 B as the number of outcomes with X 5 2, so h(2; 5, 12, 20) 5 Q 12 8 RQ R 2 3 Q 20 R 5 5 77 5 .238 323 ■ In general, if the sample size n is smaller than the number of successes in the population (M), then the largest possible X value is n. However, if M , n (e.g., a sample size of 25 and only 15 successes in the population), then X can be at most M. Similarly, whenever the number of population failures (N 2 M) exceeds the sample size, the smallest possible X value is 0 (since all sampled individuals might then be failures). However, if N 2 M , n, the smallest possible X value is n 2 (N 2 M). Thus, the possible values of X satisfy the restriction max (0, n 2 (N 2 M)) # x # min (n, M). An argument parallel to that of the previous example gives the pmf of X. PROPOSITION If X is the number of S’s in a completely random sample of size n drawn from a population consisting of M S’s and (N 2 M) F’s, then the probability distribution of X, called the hypergeometric distribution, is given by P(X 5 x) 5 h(x; n, M, N) 5 M N2M Q x RQ n 2 x R N QnR (3.15) for x, an integer, satisfying max (0, n 2 N 1 M) # x # min (n, M). Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 124 CHAPTER 3 Discrete Random Variables and Probability Distributions In Example 3.35, n 5 5, M 5 12, and N 5 20, so h(x; 5, 12, 20) for x 5 0, 1, 2, 3, 4, 5 can be obtained by substituting these numbers into Equation (3.15). Example 3.36 Five individuals from an animal population thought to be near extinction in a certain region have been caught, tagged, and released to mix into the population. After they have had an opportunity to mix, a random sample of 10 of these animals is selected. Let X 5 the number of tagged animals in the second sample. If there are actually 25 animals of this type in the region, what is the probability that (a) X 5 2? (b) X # 2? The parameter values are n 5 10, M 5 5 (5 tagged animals in the population), and N 5 25, so h(x; 10, 5, 25) 5 5 QxRQ 20 R 10 2 x Q 25 R 10 x 5 0, 1, 2, 3, 4, 5 For part (a), P(X 5 2) 5 h(2; 10, 5, 25) 5 5 20 Q RQ R 2 8 25 Q R 10 5 .385 For part (b), 2 P(X # 2) 5 P(X 5 0, 1, or 2) 5 g h(x; 10, 5, 25) x50 ■ 5 .057 1 .257 1 .385 5 .699 Various statistical software packages will easily generate hypergeometric probabilities (tabulation is cumbersome because of the three parameters). As in the binomial case, there are simple expressions for E(X) and V(X) for hypergeometric rv’s. PROPOSITION The mean and variance of the hypergeometric rv X having pmf h(x; n, M, N) are E(X) 5 n #M N N2n b V(X) 5 a N21 #n#M# N a1 2 M b N The ratio M/N is the proportion of S’s in the population. If we replace M/N by p in E(X) and V(X), we get E(X) 5 np N2n # V(X) 5 a b np(1 2 p) N21 (3.16) Expression (3.16) shows that the means of the binomial and hypergeometric rv’s are equal, whereas the variances of the two rv’s differ by the factor (N 2 n)/(N 2 1), often called the finite population correction factor. This factor is less than 1, so the Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.5. Hypergeometric and Negative Binomial Distributions 125 hypergeometric variable has smaller variance than does the binomial rv. The correction factor can be written (1 2 n/N)/(1 2 1/N), which is approximately 1 when n is small relative to N. Example 3.37 (Example 3.36 continued) 5 In the animal-tagging example, n 5 10, M 5 5, and N 5 25, so p 5 25 5 .2 and E(X) 5 10(.2) 5 2 V(X) 5 15 (10)(.2)(.8) 5 (.625)(1.6) 5 1 24 If the sampling was carried out with replacement, V(X) 5 1.6. Suppose the population size N is not actually known, so the value x is observed and we wish to estimate N. It is reasonable to equate the observed sample proportion of S’s, x/n, with the population proportion, M/N, giving the estimate N̂ 5 M#n x If M 5 100, n 5 40, and x 5 16, then N̂ 5 250. ■ Our general rule of thumb in Section 3.4 stated that if sampling was without replacement but n/N was at most .05, then the binomial distribution could be used to compute approximate probabilities involving the number of S’s in the sample. A more precise statement is as follows: Let the population size, N, and number of population S’s, M, get large with the ratio M/N approaching p. Then h(x; n, M, N) approaches b(x; n, p); so for n/N small, the two are approximately equal provided that p is not too near either 0 or 1. This is the rationale for the rule. The Negative Binomial Distribution The negative binomial rv and distribution are based on an experiment satisfying the following conditions: 1. The experiment consists of a sequence of independent trials. 2. Each trial can result in either a success (S) or a failure (F). 3. The probability of success is constant from trial to trial, so P(S on trial i) 5 p for i 5 1, 2, 3, . . . . 4. The experiment continues (trials are performed) until a total of r successes have been observed, where r is a specified positive integer. The random variable of interest is X 5 the number of failures that precede the rth success; X is called a negative binomial random variable because, in contrast to the binomial rv, the number of successes is fixed and the number of trials is random. Possible values of X are 0, 1, 2, . . . . Let nb(x; r, p) denote the pmf of X. Consider nb(7; 3, p) 5 P(X 5 7), the probability that exactly 7 F's occur before the 3rd S. In order for this to happen, the 10th trial must be an S and there must be exactly 2 S's among the first 9 trials. Thus 9 9 nb(7; 3, p) 5 e a b # p2(1 2 p)7 f # p 5 a b # p3(1 2 p)7 2 2 Generalizing this line of reasoning gives the following formula for the negative binomial pmf. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 126 CHAPTER 3 Discrete Random Variables and Probability Distributions PROPOSITION The pmf of the negative binomial rv X with parameters r 5 number of S’s and p 5 P(S) is nb(x; r, p) 5 a Example 3.38 x1r21 r bp (1 2 p)x x 5 0, 1, 2, . . . r21 A pediatrician wishes to recruit 5 couples, each of whom is expecting their first child, to participate in a new natural childbirth regimen. Let p 5 P(a randomly selected couple agrees to participate). If p 5 .2, what is the probability that 15 couples must be asked before 5 are found who agree to participate? That is, with S 5 5agrees to participate6 , what is the probability that 10 F’s occur before the fifth S? Substituting r 5 5, p 5 .2, and x 5 10 into nb(x; r, p) gives nb(10; 5, .2) 5 a 14 b(.2)5(.8)10 5 .034 4 The probability that at most 10 F’s are observed (at most 15 couples are asked) is P(X # 10) 5 10 10 x50 x50 g nb(x; 5, .2) 5 (.2)5 g a x14 b(.8)x 5 .164 4 ■ In some sources, the negative binomial rv is taken to be the number of trials X 1 r rather than the number of failures. In the special case r 5 1, the pmf is nb(x; 1, p) 5 (1 2 p)xp x 5 0, 1, 2, . . . (3.17) In Example 3.12, we derived the pmf for the number of trials necessary to obtain the first S, and the pmf there is similar to Expression (3.17). Both X 5 number of F’s and Y 5 number of trials ( 5 1 1 X) are referred to in the literature as geometric random variables, and the pmf in Expression (3.17) is called the geometric distribution. The expected number of trials until the first S was shown in Example 3.19 to be 1/p, so that the expected number of F’s until the first S is (1/p) 2 1 5 (1 2 p)/p. Intuitively, we would expect to see r # (1 2 p)/pF’s before the rth S, and this is indeed E(X). There is also a simple formula for V(X). PROPOSITION If X is a negative binomial rv with pmf nb(x; r, p), then E(X) 5 r(1 2 p) p V(X) 5 r(1 2 p) p2 Finally, by expanding the binomial coefficient in front of pr(1 2 p)x and doing some cancellation, it can be seen that nb(x; r, p) is well defined even when r is not an integer. This generalized negative binomial distribution has been found to fit observed data quite well in a wide variety of applications. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.5. Hypergeometric and Negative Binomial Distributions EXERCISES 127 Section 3.5 (68–78) 68. An electronics store has received a shipment of 20 table radios that have connections for an iPod or iPhone. Twelve of these have two slots (so they can accommodate both devices), and the other eight have a single slot. Suppose that six of the 20 radios are randomly selected to be stored under a shelf where the radios are displayed, and the remaining ones are placed in a storeroom. Let X 5 the number among the radios stored under the display shelf that have two slots. a. What kind of a distribution does X have (name and values of all parameters)? b. Compute P(X 5 2), P(X # 2), and P(X $ 2). c. Calculate the mean value and standard deviation of X. 69. Each of 12 refrigerators of a certain type has been returned to a distributor because of an audible, high-pitched, oscillating noise when the refrigerators are running. Suppose that 7 of these refrigerators have a defective compressor and the other 5 have less serious problems. If the refrigerators are examined in random order, let X be the number among the first 6 examined that have a defective compressor. Compute the following: a. P(X 5 5) b. P(X # 4) c. The probability that X exceeds its mean value by more than 1 standard deviation. d. Consider a large shipment of 400 refrigerators, of which 40 have defective compressors. If X is the number among 15 randomly selected refrigerators that have defective compressors, describe a less tedious way to calculate (at least approximately) P(X # 5) than to use the hypergeometric pmf. 70. An instructor who taught two sections of engineering statistics last term, the first with 20 students and the second with 30, decided to assign a term project. After all projects had been turned in, the instructor randomly ordered them before grading. Consider the first 15 graded projects. a. What is the probability that exactly 10 of these are from the second section? b. What is the probability that at least 10 of these are from the second section? c. What is the probability that at least 10 of these are from the same section? d. What are the mean value and standard deviation of the number among these 15 that are from the second section? e. What are the mean value and standard deviation of the number of projects not among these first 15 that are from the second section? 71. A geologist has collected 10 specimens of basaltic rock and 10 specimens of granite. The geologist instructs a laboratory assistant to randomly select 15 of the specimens for analysis. a. What is the pmf of the number of granite specimens selected for analysis? b. What is the probability that all specimens of one of the two types of rock are selected for analysis? c. What is the probability that the number of granite specimens selected for analysis is within 1 standard deviation of its mean value? 72. A personnel director interviewing 11 senior engineers for four job openings has scheduled six interviews for the first day and five for the second day of interviewing. Assume that the candidates are interviewed in random order. a. What is the probability that x of the top four candidates are interviewed on the first day? b. How many of the top four candidates can be expected to be interviewed on the first day? 73. Twenty pairs of individuals playing in a bridge tournament have been seeded 1, . . . , 20. In the first part of the tournament, the 20 are randomly divided into 10 east–west pairs and 10 north–south pairs. a. What is the probability that x of the top 10 pairs end up playing east–west? b. What is the probability that all of the top five pairs end up playing the same direction? c. If there are 2n pairs, what is the pmf of X 5 the number among the top n pairs who end up playing east–west? What are E(X) and V(X)? 74. A second-stage smog alert has been called in a certain area of Los Angeles County in which there are 50 industrial firms. An inspector will visit 10 randomly selected firms to check for violations of regulations. a. If 15 of the firms are actually violating at least one regulation, what is the pmf of the number of firms visited by the inspector that are in violation of at least one regulation? b. If there are 500 firms in the area, of which 150 are in violation, approximate the pmf of part (a) by a simpler pmf. c. For X 5 the number among the 10 visited that are in violation, compute E(X) and V(X) both for the exact pmf and the approximating pmf in part (b). 75. Suppose that p 5 P(male birth) 5 .5. A couple wishes to have exactly two female children in their family. They will have children until this condition is fulfilled. a. What is the probability that the family has x male children? b. What is the probability that the family has four children? c. What is the probability that the family has at most four children? d. How many male children would you expect this family to have? How many children would you expect this family to have? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 128 CHAPTER 3 Discrete Random Variables and Probability Distributions 76. A family decides to have children until it has three children of the same gender. Assuming P(B) 5 P(G) 5 .5, what is the pmf of X 5 the number of children in the family? 77. Three brothers and their wives decide to have children until each family has two female children. What is the pmf of X 5 the total number of male children born to the brothers? What is E(X), and how does it compare to the expected number of male children born to each brother? 78. According to the article “Characterizing the Severity and Risk of Drought in the Poudre River, Colorado” (J. of Water Res. Planning and Mgmnt., 2005: 383–393), the drought length Y is the number of consecutive time intervals in which the water supply remains below a critical value y0 (a deficit), preceded by and followed by periods in which the supply exceeds this critical value (a surplus). The cited paper proposes a geometric distribution with p 5 .409 for this random variable. a. What is the probability that a drought lasts exactly 3 intervals? At most 3 intervals? b. What is the probability that the length of a drought exceeds its mean value by at least one standard deviation? 3.6 The Poisson Probability Distribution The binomial, hypergeometric, and negative binomial distributions were all derived by starting with an experiment consisting of trials or draws and applying the laws of probability to various outcomes of the experiment. There is no simple experiment on which the Poisson distribution is based, though we will shortly describe how it can be obtained by certain limiting operations. DEFINITION A discrete random variable X is said to have a Poisson distribution with parameter m (m . 0) if the pmf of X is p(x; m) 5 e2m # mx x! x 5 0, 1, 2, 3, . . . It is no accident that we are using the symbol m for the Poisson parameter; we shall see shortly that m is in fact the expected value of X. The letter e in the pmf represents the base of the natural logarithm system; its numerical value is approximately 2.71828. In contrast to the binomial and hypergeometric distributions, the Poisson distribution spreads probability over all non-negative integers, an infinite number of possibilities. It is not obvious by inspection that p(x; m) specifies a legitimate pmf, let alone that this distribution is useful. First of all, p(x; m) . 0 for every possible x value because of the requirement that m . 0. The fact that gp(x; m) 5 1 is a consequence of the Maclaurin series expansion of em (check your calculus book for this result): em 5 1 1 m 1 m2 m3 c 1 1 5 2! 3! ` mx x50 x! g (3.18) If the two extreme terms in (3.18) are multiplied by e2m and then this quantity is moved inside the summation on the far right, the result is e2m # mx x! x50 ` 15 Example 3.39 g Let X denote the number of creatures of a particular type captured in a trap during a given time period. Suppose that X has a Poisson distribution with m 5 4.5, so on average traps will contain 4.5 creatures. [The article “Dispersal Dynamics of the Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.6. The Poisson Probability Distribution 129 Bivalve Gemma Gemma in a Patchy Environment” (Ecological Monographs, 1995: 1–20) suggests this model; the bivalve Gemma gemma is a small clam.] The probability that a trap contains exactly five creatures is P(X 5 5) 5 e24.5(4.5)5 5 .1708 5! The probability that a trap has at most five creatures is 5 P(X # 5) 5 e24.5(4.5)x (4.5)2 c (4.5)5 5 e24.5 c1 1 4.5 1 1 1 d 5 .7029 ■ x! 2! 5! x50 g The Poisson Distribution as a Limit The rationale for using the Poisson distribution in many situations is provided by the following proposition. PROPOSITION Suppose that in the binomial pmf b(x; n, p), we let n S ` and p S 0 in such a way that np approaches a value m . 0. Then b(x; n, p) S p(x; m). According to this proposition, in any binomial experiment in which n is large and p is small, b(x; n, p) < p(x; m), where m 5 np. As a rule of thumb, this approximation can safely be applied if n . 50 and np , 5. Example 3.40 If a publisher of nontechnical books takes great pains to ensure that its books are free of typographical errors, so that the probability of any given page containing at least one such error is .005 and errors are independent from page to page, what is the probability that one of its 400-page novels will contain exactly one page with errors? At most three pages with errors? With S denoting a page containing at least one error and F an error-free page, the number X of pages containing at least one error is a binomial rv with n 5 400 and p 5 .005, so np 5 2. We wish P(X 5 1) 5 b(1; 400, .005) < p(1; 2) 5 e22(2)1 5 .270671 1! The binomial value is b(1; 400, .005) 5 .270669, so the approximation is very good. Similarly, P(X # 3) < 3 3 x50 x50 g p(x, 2) 5 g e22 2x x! 5 .135335 1 .270671 1 .270671 1 .180447 5 .8571 and this again is quite close to the binomial value P(X # 3) 5 .8576. ■ Table 3.2 shows the Poisson distribution for m 5 3 along with three binomial distributions with np 5 3, and Figure 3.8 (from S-Plus) plots the Poisson along with the first two binomial distributions. The approximation is of limited use for n 5 30, but of course the accuracy is better for n 5 100 and much better for n 5 300. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 130 CHAPTER 3 Discrete Random Variables and Probability Distributions Table 3.2 Comparing the Poisson and Three Binomial Distributions x n 5 30, p 5 .1 n 5 100, p 5 .03 n 5 300, p 5 .01 Poisson, m 5 3 0 1 2 3 4 5 6 7 8 9 10 0.042391 0.141304 0.227656 0.236088 0.177066 0.102305 0.047363 0.018043 0.005764 0.001565 0.000365 0.047553 0.147070 0.225153 0.227474 0.170606 0.101308 0.049610 0.020604 0.007408 0.002342 0.000659 0.049041 0.148609 0.224414 0.225170 0.168877 0.100985 0.050153 0.021277 0.007871 0.002580 0.000758 0.049787 0.149361 0.224042 0.224042 0.168031 0.100819 0.050409 0.021604 0.008102 0.002701 0.000810 p(x) Bin, n⫽30 (o); Bin, n⫽100 (x); Poisson ( ) .25 o x o x .20 o x .15 x o o x .10 .05 x o x o x o x o 0 0 Figure 3.8 2 4 6 8 x o x o x 10 Comparing a Poisson and two binomial distributions Appendix Table A.2 exhibits the cdf F(x; m) for m 5 .1, .2, . . . , 1, 2, . . . , 10, 15, and 20. For example, if m 5 2, then P(X # 3) 5 F(3; 2) 5 .857 as in Example 3.40, whereas P(X 5 3) 5 F(3; 2) 2 F(2; 2) 5 .180. Alternatively, many statistical computer packages will generate p(x; m) and F(x; m) upon request. The Mean and Variance of X Since b(x; n, p) S p(x; m) as n S ` , p S 0, np S m, the mean and variance of a binomial variable should approach those of a Poisson variable. These limits are np S m and np(1 2 p) S m. PROPOSITION If X has a Poisson distribution with parameter m, then E(X) 5 V(X) 5 m. These results can also be derived directly from the definitions of mean and variance. Example 3.41 (Example 3.39 continued) Both the expected number of creatures trapped and the variance of the number trapped equal 4.5, and sX 5 1m 5 14.5 5 2.12. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 3.6. The Poisson Probability Distribution 131 The Poisson Process A very important application of the Poisson distribution arises in connection with the occurrence of events of some type over time. Events of interest might be visits to a particular website, pulses of some sort recorded by a counter, email messages sent to a particular address, accidents in an industrial facility, or cosmic ray showers observed by astronomers at a particular observatory. We make the following assumptions about the way in which the events of interest occur: 1. There exists a parameter a . 0 such that for any short time interval of length ⌬t, the probability that exactly one event occurs is a # ⌬t 1 o(⌬t).* 2. The probability of more than one event occurring during ⌬t is o(⌬t) [which, along with Assumption 1, implies that the probability of no events during ⌬t is 1 2 a # ⌬t 2 o(⌬t)]. 3. The number of events occurring during the time interval ⌬t is independent of the number that occur prior to this time interval. Informally, Assumption 1 says that for a short interval of time, the probability of a single event occurring is approximately proportional to the length of the time interval, where a is the constant of proportionality. Now let Pk(t) denote the probability that k events will be observed during any particular time interval of length t. PROPOSITION Pk(t) 5 e2at # (at)k/k!, so that the number of events during a time interval of length t is a Poisson rv with parameter m 5 at. The expected number of events during any such time interval is then at, so the expected number during a unit interval of time is a. The occurrence of events over time as described is called a Poisson process; the parameter a specifies the rate for the process. Example 3.42 Suppose pulses arrive at a counter at an average rate of six per minute, so that a 5 6. To find the probability that in a .5-min interval at least one pulse is received, note that the number of pulses in such an interval has a Poisson distribution with parameter at 5 6(.5) 5 3 (.5 min is used because a is expressed as a rate per minute). Then with X 5 the number of pulses received in the 30-sec interval, P(1 # X) 5 1 2 P(X 5 0) 5 1 2 e23(3)0 5 .950 0! ■ Instead of observing events over time, consider observing events of some type that occur in a two- or three-dimensional region. For example, we might select on a map a certain region R of a forest, go to that region, and count the number of trees. Each tree would represent an event occurring at a particular point in space. Under assumptions similar to 1–3, it can be shown that the number of events occurring in a region R has a Poisson distribution with parameter a # a(R), where a(R) is the area of R. The quantity a is the expected number of events per unit area or volume. * A quantity is o(⌬t) (read “little o of delta t”) if, as ⌬t approaches 0, so does o(⌬t)/⌬t. That is, o(⌬t) is even more negligible (approaches 0 faster) than ⌬t itself. The quantity (⌬t)2 has this property, but sin(⌬t) does not. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 132 CHAPTER 3 EXERCISES Discrete Random Variables and Probability Distributions Section 3.6 (79–93) 79. Let X, the number of flaws on the surface of a randomly selected boiler of a certain type, have a Poisson distribution with parameter m 5 5. Use Appendix Table A.2 to compute the following probabilities: a. P(X # 8) b. P(X 5 8) c. P(9 # X) d. P(5 # X # 8) e. P(5 , X , 8) 80. Let X be the number of material anomalies occurring in a particular region of an aircraft gas-turbine disk. The article “Methodology for Probabilistic Life Prediction of MultipleAnomaly Materials” (Amer. Inst. of Aeronautics and Astronautics J., 2006: 787–793) proposes a Poisson distribution for X. Suppose that m 5 4. a. Compute both P(X # 4) and P(X , 4). b. Compute P(4 # X # 8). c. Compute P(8 # X). d. What is the probability that the number of anomalies exceeds its mean value by no more than one standard deviation? 81. Suppose that the number of drivers who travel between a particular origin and destination during a designated time period has a Poisson distribution with parameter m 5 20 (suggested in the article “Dynamic Ride Sharing: Theory and Practice,” J. of Transp. Engr., 1997: 308–312). What is the probability that the number of drivers will a. Be at most 10? b. Exceed 20? c. Be between 10 and 20, inclusive? Be strictly between 10 and 20? d. Be within 2 standard deviations of the mean value? 82. Consider writing onto a computer disk and then sending it through a certifier that counts the number of missing pulses. Suppose this number X has a Poisson distribution with parameter m 5 .2. (Suggested in “Average Sample Number for Semi-Curtailed Sampling Using the Poisson Distribution,” J. Quality Technology, 1983: 126–129.) a. What is the probability that a disk has exactly one missing pulse? b. What is the probability that a disk has at least two missing pulses? c. If two disks are independently selected, what is the probability that neither contains a missing pulse? 83. An article in the Los Angeles Times (Dec. 3, 1993) reports that 1 in 200 people carry the defective gene that causes inherited colon cancer. In a sample of 1000 individuals, what is the approximate distribution of the number who carry this gene? Use this distribution to calculate the approximate probability that a. Between 5 and 8 (inclusive) carry the gene. b. At least 8 carry the gene. 84. Suppose that only .10% of all computers of a certain type experience CPU failure during the warranty period. Consider a sample of 10,000 computers. a. What are the expected value and standard deviation of the number of computers in the sample that have the defect? b. What is the (approximate) probability that more than 10 sampled computers have the defect? c. What is the (approximate) probability that no sampled computers have the defect? 85. Suppose small aircraft arrive at a certain airport according to a Poisson process with rate a 5 8 per hour, so that the number of arrivals during a time period of t hours is a Poisson rv with parameter m 5 8t. a. What is the probability that exactly 6 small aircraft arrive during a 1-hour period? At least 6? At least 10? b. What are the expected value and standard deviation of the number of small aircraft that arrive during a 90-min period? c. What is the probability that at least 20 small aircraft arrive during a 2.5-hour period? That at most 10 arrive during this period? 86. The number of people arriving for treatment at an emergency room can be modeled by a Poisson process with a rate parameter of five per hour. a. What is the probability that exactly four arrivals occur during a particular hour? b. What is the probability that at least four people arrive during a particular hour? c. How many people do you expect to arrive during a 45min period? 87. The number of requests for assistance received by a towing service is a Poisson process with rate a 5 4 per hour. a. Compute the probability that exactly ten requests are received during a particular 2-hour period. b. If the operators of the towing service take a 30-min break for lunch, what is the probability that they do not miss any calls for assistance? c. How many calls would you expect during their break? 88. In proof testing of circuit boards, the probability that any particular diode will fail is .01. Suppose a circuit board contains 200 diodes. a. How many diodes would you expect to fail, and what is the standard deviation of the number that are expected to fail? b. What is the (approximate) probability that at least four diodes will fail on a randomly selected board? c. If five boards are shipped to a particular customer, how likely is it that at least four of them will work properly? (A board works properly only if all its diodes work.) 89. The article “Reliability-Based Service-Life Assessment of Aging Concrete Structures” (J. Structural Engr., 1993: 1600–1621) suggests that a Poisson process can be used to represent the occurrence of structural loads over time. Suppose the mean time between occurrences of loads is .5 year. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Supplementary Exercises a. How many loads can be expected to occur during a 2year period? b. What is the probability that more than five loads occur during a 2-year period? c. How long must a time period be so that the probability of no loads occurring during that period is at most .1? 90. Let X have a Poisson distribution with parameter m. Show that E(X) 5 m directly from the definition of expected value. [Hint: The first term in the sum equals 0, and then x can be canceled. Now factor out m and show that what is left sums to 1.] 91. Suppose that trees are distributed in a forest according to a two-dimensional Poisson process with parameter a, the expected number of trees per acre, equal to 80. a. What is the probability that in a certain quarter-acre plot, there will be at most 16 trees? b. If the forest covers 85,000 acres, what is the expected number of trees in the forest? c. Suppose you select a point in the forest and construct a circle of radius .1 mile. Let X 5 the number of trees within that circular region. What is the pmf of X? [Hint: 1 sq mile 5 640 acres.] 92. Automobiles arrive at a vehicle equipment inspection station according to a Poisson process with rate a 5 10 per hour. Suppose that with probability .5 an arriving vehicle will have no equipment violations. SUPPLEMENTARY EXERCISES 95. After shuffling a deck of 52 cards, a dealer deals out 5. Let X 5 the number of suits represented in the five-card hand. a. Show that the pmf of X is p(x) a. What is the probability that exactly ten arrive during the hour and all ten have no violations? b. For any fixed y $ 10, what is the probability that y arrive during the hour, of which ten have no violations? c. What is the probability that ten “no-violation” cars arrive during the next hour? [Hint: Sum the probabilities in part (b) from y 5 10 to ⬁.] 93. a. In a Poisson process, what has to happen in both the time interval (0, t) and the interval (t, t 1 ⌬t) so that no events occur in the entire interval (0, t 1 ⌬t)? Use this and Assumptions 1–3 to write a relationship between P0 (t 1 ⌬t) and P0(t). b. Use the result of part (a) to write an expression for the difference P0 (t 1 ⌬t) 2 P0 (t). Then divide by ⌬t and let ⌬t S 0 to obtain an equation involving (d/dt)P0 (t), the derivative of P0(t) with respect to t. c. Verify that P0 (t) 5 e2at satisfies the equation of part (b). d. It can be shown in a manner similar to parts (a) and (b) that the Pk (t)s must satisfy the system of differential equations d P (t) 5 aPk21(t) 2 aPk (t) dt k k 5 1, 2, 3, . . . Verify that Pk(t) 5 e2at(at)k/k! satisfies the system. (This is actually the only solution.) (94–122) 94. Consider a deck consisting of seven cards, marked 1, 2, . . . , 7. Three of these cards are selected at random. Define an rv W by W 5 the sum of the resulting numbers, and compute the pmf of W. Then compute m and s2. [Hint: Consider outcomes as unordered, so that (1, 3, 7) and (3, 1, 7) are not different outcomes. Then there are 35 outcomes, and they can be listed. (This type of rv actually arises in connection with a statistical procedure called Wilcoxon’s rank-sum test, in which there is an x sample and a y sample and W is the sum of the ranks of the x’s in the combined sample; see Section 15.2.) x 133 1 2 3 4 .002 .146 .588 .264 [Hint: p(1) 5 4P(all are spades), p(2) 5 6P(only spades and hearts with at least one of each suit), and p(4) 5 4P(2 spades ¨ one of each other suit).] b. Compute m, s2, and s. 96. The negative binomial rv X was defined as the number of F’s preceding the rth S. Let Y 5 the number of trials necessary to obtain the rth S. In the same manner in which the pmf of X was derived, derive the pmf of Y. 97. Of all customers purchasing automatic garage-door openers, 75% purchase a chain-driven model. Let X 5 the number among the next 15 purchasers who select the chain-driven model. a. What is the pmf of X? b. Compute P(X . 10). c. Compute P(6 # X # 10). d. Compute m and s2. e. If the store currently has in stock 10 chain-driven models and 8 shaft-driven models, what is the probability that the requests of these 15 customers can all be met from existing stock? 98. A friend recently planned a camping trip. He had two flashlights, one that required a single 6-V battery and another that used two size-D batteries. He had previously packed two 6-V and four size-D batteries in his camper. Suppose the probability that any particular battery works is p and that batteries work or fail independently of one another. Our friend wants to take just one flashlight. For what values of p should he take the 6-V flashlight? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 134 CHAPTER 3 Discrete Random Variables and Probability Distributions 99. A k-out-of-n system is one that will function if and only if at least k of the n individual components in the system function. If individual components function independently of one another, each with probability .9, what is the probability that a 3-out-of-5 system functions? 100. A manufacturer of integrated circuit chips wishes to control the quality of its product by rejecting any batch in which the proportion of defective chips is too high. To this end, out of each batch (10,000 chips), 25 will be selected and tested. If at least 5 of these 25 are defective, the entire batch will be rejected. a. What is the probability that a batch will be rejected if 5% of the chips in the batch are in fact defective? b. Answer the question posed in (a) if the percentage of defective chips in the batch is 10%. c. Answer the question posed in (a) if the percentage of defective chips in the batch is 20%. d. What happens to the probabilities in (a)–(c) if the critical rejection number is increased from 5 to 6? 101. Of the people passing through an airport metal detector, .5% activate it; let X 5 the number among a randomly selected group of 500 who activate the detector. a. What is the (approximate) pmf of X? b. Compute P(X 5 5). c. Compute P(5 # X). 102. An educational consulting firm is trying to decide whether high school students who have never before used a handheld calculator can solve a certain type of problem more easily with a calculator that uses reverse Polish logic or one that does not use this logic. A sample of 25 students is selected and allowed to practice on both calculators. Then each student is asked to work one problem on the reverse Polish calculator and a similar problem on the other. Let p 5 P(S), where S indicates that a student worked the problem more quickly using reverse Polish logic than without, and let X 5 number of S’s. a. If p 5 .5, what is P(7 # X # 18)? b. If p 5 .8, what is P(7 # X # 18)? c. If the claim that p 5 .5 is to be rejected when either x # 7 or x $ 18, what is the probability of rejecting the claim when it is actually correct? d. If the decision to reject the claim p 5 .5 is made as in part (c), what is the probability that the claim is not rejected when p 5 .6? When p 5 .8? e. What decision rule would you choose for rejecting the claim p 5 .5 if you wanted the probability in part (c) to be at most .01? 103. Consider a disease whose presence can be identified by carrying out a blood test. Let p denote the probability that a randomly selected individual has the disease. Suppose n individuals are independently selected for testing. One way to proceed is to carry out a separate test on each of the n blood samples. A potentially more economical approach, group testing, was introduced during World War II to identify syphilitic men among army inductees. First, take a part of each blood sample, combine these specimens, and carry out a single test. If no one has the disease, the result will be negative, and only the one test is required. If at least one individual is diseased, the test on the combined sample will yield a positive result, in which case the n individual tests are then carried out. If p 5 .1 and n 5 3, what is the expected number of tests using this procedure? What is the expected number when n 5 5? [The article “Random Multiple-Access Communication and Group Testing” (IEEE Trans. on Commun., 1984: 769–774) applied these ideas to a communication system in which the dichotomy was active/idle user rather than diseased/nondiseased.] 104. Let p1 denote the probability that any particular code symbol is erroneously transmitted through a communication system. Assume that on different symbols, errors occur independently of one another. Suppose also that with probability p2 an erroneous symbol is corrected upon receipt. Let X denote the number of correct symbols in a message block consisting of n symbols (after the correction process has ended). What is the probability distribution of X? 105. The purchaser of a power-generating unit requires c consecutive successful start-ups before the unit will be accepted. Assume that the outcomes of individual start-ups are independent of one another. Let p denote the probability that any particular start-up is successful. The random variable of interest is X 5 the number of start-ups that must be made prior to acceptance. Give the pmf of X for the case c 5 2. If p 5 .9, what is P(X # 8)? [Hint: For x $ 5, express p(x) “recursively” in terms of the pmf evaluated at the smaller values x 2 3, x 2 4, c, 2.] (This problem was suggested by the article “Evaluation of a Start-Up Demonstration Test,” J. Quality Technology, 1983: 103–106.) 106. A plan for an executive travelers’ club has been developed by an airline on the premise that 10% of its current customers would qualify for membership. a. Assuming the validity of this premise, among 25 randomly selected current customers, what is the probability that between 2 and 6 (inclusive) qualify for membership? b. Again assuming the validity of the premise, what are the expected number of customers who qualify and the standard deviation of the number who qualify in a random sample of 100 current customers? c. Let X denote the number in a random sample of 25 current customers who qualify for membership. Consider rejecting the company’s premise in favor of the claim that p . .10 if x $ 7. What is the probability that the company’s premise is rejected when it is actually valid? d. Refer to the decision rule introduced in part (c). What is the probability that the company’s premise is not rejected even though p 5 .20 (i.e., 20% qualify)? 107. Forty percent of seeds from maize (modern-day corn) ears carry single spikelets, and the other 60% carry paired spikelets. A seed with single spikelets will produce an ear Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Supplementary Exercises with single spikelets 29% of the time, whereas a seed with paired spikelets will produce an ear with single spikelets 26% of the time. Consider randomly selecting ten seeds. a. What is the probability that exactly five of these seeds carry a single spikelet and produce an ear with a single spikelet? b. What is the probability that exactly five of the ears produced by these seeds have single spikelets? What is the probability that at most five ears have single spikelets? 108. A trial has just resulted in a hung jury because eight members of the jury were in favor of a guilty verdict and the other four were for acquittal. If the jurors leave the jury room in random order and each of the first four leaving the room is accosted by a reporter in quest of an interview, what is the pmf of X 5 the number of jurors favoring acquittal among those interviewed? How many of those favoring acquittal do you expect to be interviewed? 109. A reservation service employs five information operators who receive requests for information independently of one another, each according to a Poisson process with rate a 5 2 per minute. a. What is the probability that during a given 1-min period, the first operator receives no requests? b. What is the probability that during a given 1-min period, exactly four of the five operators receive no requests? c. Write an expression for the probability that during a given 1-min period, all of the operators receive exactly the same number of requests. 110. Grasshoppers are distributed at random in a large field according to a Poisson process with parameter a 5 2 per square yard. How large should the radius R of a circular sampling region be taken so that the probability of finding at least one in the region equals .99? 111. A newsstand has ordered five copies of a certain issue of a photography magazine. Let X 5 the number of individuals who come in to purchase this magazine. If X has a Poisson distribution with parameter m 5 4, what is the expected number of copies that are sold? 112. Individuals A and B begin to play a sequence of chess games. Let S 5 5A wins a game6 , and suppose that outcomes of successive games are independent with P(S) 5 p and P(F) 5 1 2 p (they never draw). They will play until one of them wins ten games. Let X 5 the number of games played (with possible values 10, 11, . . . , 19). a. For x 5 10, 11, c, 19, obtain an expression for p(x) 5 P(X 5 x). b. If a draw is possible, with p 5 P(S), q 5 P(F), 1 2 p 2 q 5 P(draw), what are the possible values of X? What is P(20 # X) ? [Hint: P(20 # X) 5 1 2 P(X , 20).] 113. A test for the presence of a certain disease has probability .20 of giving a false-positive reading (indicating that an individual has the disease when this is not the case) and 135 probability .10 of giving a false-negative result. Suppose that ten individuals are tested, five of whom have the disease and five of whom do not. Let X 5 the number of positive readings that result. a. Does X have a binomial distribution? Explain your reasoning. b. What is the probability that exactly three of the ten test results are positive? 114. The generalized negative binomial pmf is given by nb(x; r, p) 5 k(r, x) # pr(1 2 p)x x 5 0, 1, 2, . . . Let X, the number of plants of a certain species found in a particular region, have this distribution with p 5 .3 and r 5 2.5. What is P(X 5 4)? What is the probability that at least one plant is found? 115. There are two Certified Public Accountants in a particular office who prepare tax returns for clients. Suppose that for a particular type of complex form, the number of errors made by the first preparer has a Poisson distribution with mean value m1, the number of errors made by the second preparer has a Poisson distribution with mean value m2, and that each CPA prepares the same number of forms of this type. Then if a form of this type is randomly selected, the function p(x; m1, m2) 5 .5 e2m1mx1 e2m2mx2 1 .5 x! x! x 5 0, 1, 2, . . . gives the pmf of X 5 the number of errors on the selected form. a. Verify that p(x; m1, m2) is in fact a legitimate pmf ($ 0 and sums to 1). b. What is the expected number of errors on the selected form? c. What is the variance of the number of errors on the selected form? d. How does the pmf change if the first CPA prepares 60% of all such forms and the second prepares 40%? 116. The mode of a discrete random variable X with pmf p(x) is that value x* for which p(x) is largest (the most probable x value). a. Let X | Bin(n, p). By considering the ratio b(x 1 1; n, p)/b(x; n, p), show that b(x; n, p) increases with x as long as x , np 2 (1 2 p). Conclude that the mode x* is the integer satisfying (n 1 1)p 2 1 # x* # (n 1 1)p. b. Show that if X has a Poisson distribution with parameter m, the mode is the largest integer less than m. If m is an integer, show that both m 2 1 and m are modes. 117. A computer disk storage device has ten concentric tracks, numbered 1, 2, . . . , 10 from outermost to innermost, and a single access arm. Let pi 5 the probability that any particular request for data will take the arm to track i(i 5 1, . . . , 10). Assume that the tracks accessed in successive seeks are independent. Let X 5 the number of Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 136 CHAPTER 3 Discrete Random Variables and Probability Distributions tracks over which the access arm passes during two successive requests (excluding the track that the arm has just left, so possible X values are x 5 0, 1, . . . , 9). Compute the pmf of X. [Hint: P(the arm is now on track i and X 5 j) 5 P(X 5 j|arm now on i) # p.i After the conditional probability is written in terms of p1, . . . , p10, by the law of total probability, the desired probability is obtained by summing over i.] 118. If X is a hypergeometric rv, show directly from the definition that E(X) 5 nM/N (consider only the case n , M). [Hint: Factor nM/N out of the sum for E(X), and show that the terms inside the sum are of the form h(y; n 2 1, M 2 1, N 2 1), where y 5 x 2 1.] 119. Use the fact that g (x 2 m)2p(x) $ g (x 2 m)2p(x) x: u x2mu$ks all x to prove Chebyshev’s inequality given in Exercise 44. 120. The simple Poisson process of Section 3.6 is characterized by a constant rate a at which events occur per unit time. A generalization of this is to suppose that the probability of exactly one event occurring in the interval [t, t 1 ⌬t] is a(t) # ⌬t 1 o(⌬t). It can then be shown that the number of events occurring during an interval [t1, t2] has a Poisson distribution with parameter m5 冮 t1 a(t) dt t2 The occurrence of events over time in this situation is called a nonhomogeneous Poisson process. The article “Inference Based on Retrospective Ascertainment,” J. Amer. Stat. Assoc., 1989: 360–372, considers the intensity function a(t) 5 ea1bt as appropriate for events involving transmission of HIV (the AIDS virus) via blood transfusions. Suppose that a 5 2 and b 5 .6 (close to values suggested in the paper), with time in years. a. What is the expected number of events in the interval [0, 4]? In [2, 6]? b. What is the probability that at most 15 events occur in the interval [0, .9907]? 121. Consider a collection A1, . . . , Ak of mutually exclusive and exhaustive events, and a random variable X whose distribution depends on which of the Ai’s occurs (e.g., a commuter might select one of three possible routes from home to work, with X representing the commute time). Let E(Xu Ai) denote the expected value of X given that the event Ai occurs. Then it can be shown that E(X) 5 ⌺E(Xu Ai) # P(Ai), the weighted average of the individual “conditional expectations” where the weights are the probabilities of the partitioning events. a. The expected duration of a voice call to a particular telephone number is 3 minutes, whereas the expected duration of a data call to that same number is 1 minute. If 75% of all calls are voice calls, what is the expected duration of the next call? b. A deli sells three different types of chocolate chip cookies. The number of chocolate chips in a type i cookie has a Poisson distribution with parameter mi 5 i 1 1 (i 5 1, 2, 3). If 20% of all customers purchasing a chocolate chip cookie select the first type, 50% choose the second type, and the remaining 30% opt for the third type, what is the expected number of chips in a cookie purchased by the next customer? 122. Consider a communication source that transmits packets containing digitized speech. After each transmission, the receiver sends a message indicating whether the transmission was successful or unsuccessful. If a transmission is unsuccessful, the packet is re-sent. Suppose a voice packet can be transmitted a maximum of 10 times. Assuming that the results of successive transmissions are independent of one another and that the probability of any particular transmission being successful is p, determine the probability mass function of the rv X 5 the number of times a packet is transmitted. Then obtain an expression for the expected number of times a packet is transmitted. Bibliography Johnson, Norman, Samuel Kotz, and Adrienne Kemp, Discrete Univariate Distributions, Wiley, New York, 1992. An encyclopedia of information on discrete distributions. Olkin, Ingram, Cyrus Derman, and Leon Gleser, Probability Models and Applications (2nd ed.), Macmillan, New York, 1994. Contains an in-depth discussion of both general properties of discrete and continuous distributions and results for specific distributions. Ross, Sheldon, Introduction to Probability Models (9th ed.), Academic Press, New York, 2007. A good source of material on the Poisson process and generalizations and a nice introduction to other topics in applied probability. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4 Continuous Random Variables and Probability Distributions INTRODUCTION Chapter 3 concentrated on the development of probability distributions for discrete random variables. In this chapter, we consider the second general type of random variable that arises in many applied problems. Sections 4.1 and 4.2 present the basic definitions and properties of continuous random variables and their probability distributions. In Section 4.3, we study in detail the normal random variable and distribution, unquestionably the most important and useful in probability and statistics. Sections 4.4 and 4.5 discuss some other continuous distributions that are often used in applied work. In Section 4.6, we introduce a method for assessing whether given sample data is consistent with a specified distribution. 137 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 138 CHAPTER 4 Continuous Random Variables and Probability Distributions 4.1 Probability Density Functions A discrete random variable (rv) is one whose possible values either constitute a finite set or else can be listed in an infinite sequence (a list in which there is a first element, a second element, etc.). A random variable whose set of possible values is an entire interval of numbers is not discrete. Recall from Chapter 3 that a random variable X is continuous if (1) possible values comprise either a single interval on the number line (for some A , B, any number x between A and B is a possible value) or a union of disjoint intervals, and (2) P(X 5 c) 5 0 for any number c that is a possible value of X. Example 4.1 If in the study of the ecology of a lake, we make depth measurements at randomly chosen locations, then X 5 the depth at such a location is a continuous rv. Here A is the minimum depth in the region being sampled, and B is the maximum depth. ■ Example 4.2 If a chemical compound is randomly selected and its pH X is determined, then X is a continuous rv because any pH value between 0 and 14 is possible. If more is known about the compound selected for analysis, then the set of possible values might be a subinterval of [0, 14], such as 5.5 # x # 6.5, but X would still be continuous. ■ Example 4.3 Let X represent the amount of time a randomly selected customer spends waiting for a haircut before his/her haircut commences. Your first thought might be that X is a continuous random variable, since a measurement is required to determine its value. However, there are customers lucky enough to have no wait whatsoever before climbing into the barber’s chair. So it must be the case that P(X 5 0) . 0. Conditional on no chairs being empty, though, the waiting time will be continuous since X could then assume any value between some minimum possible time A and a maximum possible time B. This random variable is neither purely discrete nor purely continuous but instead is a mixture of the two types. ■ One might argue that although in principle variables such as height, weight, and temperature are continuous, in practice the limitations of our measuring instruments restrict us to a discrete (though sometimes very finely subdivided) world. However, continuous models often approximate real-world situations very well, and continuous mathematics (the calculus) is frequently easier to work with than mathematics of discrete variables and distributions. Probability Distributions for Continuous Variables Suppose the variable X of interest is the depth of a lake at a randomly chosen point on the surface. Let M 5 the maximum depth (in meters), so that any number in the interval [0, M] is a possible value of X. If we “discretize” X by measuring depth to the nearest meter, then possible values are nonnegative integers less than or equal to M. The resulting discrete distribution of depth can be pictured using a probability histogram. If we draw the histogram so that the area of the rectangle above any possible integer k is the proportion of the lake whose depth is (to the nearest meter) k, then the total area of all rectangles is 1. A possible histogram appears in Figure 4.1(a). If depth is measured much more accurately and the same measurement axis as in Figure 4.1(a) is used, each rectangle in the resulting probability histogram is much narrower, though the total area of all rectangles is still 1. A possible histogram is Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.1 Probability Density Functions 139 pictured in Figure 4.1(b); it has a much smoother appearance than the histogram in Figure 4.1(a). If we continue in this way to measure depth more and more finely, the resulting sequence of histograms approaches a smooth curve, such as is pictured in Figure 4.1(c). Because for each histogram the total area of all rectangles equals 1, the total area under the smooth curve is also 1. The probability that the depth at a randomly chosen point is between a and b is just the area under the smooth curve between a and b. It is exactly a smooth curve of the type pictured in Figure 4.1(c) that specifies a continuous probability distribution. 0 M 0 M (a) 0 M (b) (c) Figure 4.1 (a) Probability histogram of depth measured to the nearest meter; (b) probability histogram of depth measured to the nearest centimeter; (c) a limit of a sequence of discrete histograms DEFINITION Let X be a continuous rv. Then a probability distribution or probability density function (pdf) of X is a function f(x) such that for any two numbers a and b with a # b, b P(a # X # b) 5 3 f(x)dx a That is, the probability that X takes on a value in the interval [a, b] is the area above this interval and under the graph of the density function, as illustrated in Figure 4.2. The graph of f(x) is often referred to as the density curve. f(x) x a Figure 4.2 b P(a # X # b) 5 the area under the density curve between a and b For f(x) to be a legitimate pdf, it must satisfy the following two conditions: 1. f(x) $ 0 for all x ` 2. 3 f(x) dx 5 area under the entire graph of f(x) 2` 51 Example 4.4 The direction of an imperfection with respect to a reference line on a circular object such as a tire, brake rotor, or flywheel is, in general, subject to uncertainty. Consider the reference line connecting the valve stem on a tire to the center point, and let X Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 140 CHAPTER 4 Continuous Random Variables and Probability Distributions be the angle measured clockwise to the location of an imperfection. One possible pdf for X is 1 0 # x , 360 360 f(x) 5 • 0 otherwise The pdf is graphed in Figure 4.3. Clearly f(x) $ 0. The area under the density curve 1 R(360) 5 1. The probability that is just the area of a rectangle: (height)(base) 5 Q360 the angle is between 908 and 1808 is 180 P(90 # X # 180) 5 3 90 x5180 1 x 1 dx 5 5 5 .25 ` 360 360 x590 4 The probability that the angle of occurrence is within 908 of the reference line is P(0 # X # 90) 1 P(270 # X , 360) 5 .25 1 .25 5 .50 f(x) f(x) Shaded area P(90 X 180) 1 360 x 0 360 Figure 4.3 x 90 180 270 360 The pdf and probability from Example 4.4 ■ Because whenever 0 # a # b # 360 in Example 4.4 and P(a # X # b) depends only on the width b 2 a of the interval, X is said to have a uniform distribution. DEFINITION A continuous rv X is said to have a uniform distribution on the interval [A, B] if the pdf of X is 1 A#x#B f(x; A, B) 5 • B 2 A 0 otherwise The graph of any uniform pdf looks like the graph in Figure 4.3 except that the interval of positive density is [A, B] rather than [0, 360]. In the discrete case, a probability mass function (pmf) tells us how little “blobs” of probability mass of various magnitudes are distributed along the measurement axis. In the continuous case, probability density is “smeared” in a continuous fashion along the interval of possible values. When density is smeared uniformly over the interval, a uniform pdf, as in Figure 4.3, results. When X is a discrete random variable, each possible value is assigned positive probability. This is not true of a continuous random variable (that is, the second Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.1 Probability Density Functions 141 condition of the definition is satisfied) because the area under a density curve that lies above any single value is zero: c c1e P(X 5 c) 5 3 f(x) dx 5 lim 3 eS0 c f(x) dx 5 0 c2e The fact that P(X 5 c) 5 0 when X is continuous has an important practical consequence: The probability that X lies in some interval between a and b does not depend on whether the lower limit a or the upper limit b is included in the probability calculation: (4.1) P(a # X # b) 5 P(a , X , b) 5 P(a , X # b) 5 P(a # X , b) If X is discrete and both a and b are possible values (e.g., X is binomial with n 5 20 and a 5 5, b 5 10), then all four of the probabilities in (4.1) are different. The zero probability condition has a physical analog. Consider a solid circular rod with cross-sectional area 5 1 in2. Place the rod alongside a measurement axis and suppose that the density of the rod at any point x is given by the value f(x) of a density function. Then if the rod is sliced at points a and b and this segment is removed, the amount of mass removed is 冕 ba f(x) dx; if the rod is sliced just at the point c, no mass is removed. Mass is assigned to interval segments of the rod but not to individual points. Example 4.5 “Time headway” in traffic flow is the elapsed time between the time that one car finishes passing a fixed point and the instant that the next car begins to pass that point. Let X 5 the time headway for two randomly chosen consecutive cars on a freeway during a period of heavy flow. The following pdf of X is essentially the one suggested in “The Statistical Properties of Freeway Traffic” (Transp. Res., vol. 11: 221–228): f(x) 5 e .15e2.15(x2.5) x $ .5 0 otherwise The graph of f (x) is given in Figure 4.4; there is no density associated with headway times less than .5, and headway density decreases rapidly (exponentially fast) as x increases from .5. Clearly, f(x) $ 0; to show that 冕 `2` f (x) dx 5 1, we use the calculus result 冕 `a e2kx dx 5 (1/k)e2k # a. Then ` ` ` 2.15(x2.5) dx 5 .15e.075 3 e2.15x dx 3 f(x) dx 5 3 .15e .5 2` .5 5 .15e.075 # 1 2(.15)(.5) e 51 .15 f (x) .15 P(X 5) x 0 2 4 6 8 10 .5 Figure 4.4 The density curve for time headway in Example 4.5 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 142 CHAPTER 4 Continuous Random Variables and Probability Distributions The probability that headway time is at most 5 sec is 5 P(X # 5) 5 3 5 f(x) dx 5 3 .15e2.15(x2.5) dx .5 2` 5 .15e.075 3 e2.15x dx 5 .15e.075 # a2 5 .5 1 2.15x x55 e b ` .15 x5.5 5 e.075(2e2.75 1 e2.075) 5 1.078(2.472 1 .928) 5 .491 5 P(less than 5 sec) 5 P(X , 5) ■ Unlike discrete distributions such as the binomial, hypergeometric, and negative binomial, the distribution of any given continuous rv cannot usually be derived using simple probabilistic arguments. Instead, one must make a judicious choice of pdf based on prior knowledge and available data. Fortunately, there are some general families of pdf’s that have been found to be sensible candidates in a wide variety of experimental situations; several of these are discussed later in the chapter. Just as in the discrete case, it is often helpful to think of the population of interest as consisting of X values rather than individuals or objects. The pdf is then a model for the distribution of values in this numerical population, and from this model various population characteristics (such as the mean) can be calculated. EXERCISES Section 4.1 (1–10) 1. The current in a certain circuit as measured by an ammeter is a continuous random variable X with the following density function: f(x) 5 e .075x 1 .2 3 # x # 5 0 otherwise a. Graph the pdf and verify that the total area under the density curve is indeed 1. b. Calculate P(X # 4). How does this probability compare to P(X , 4)? c. Calculate P(3.5 # X # 4.5) and also P(4.5 , X). 2. Suppose the reaction temperature X (in 8C) in a certain chemical process has a uniform distribution with A 5 25 and B 5 5. a. Compute P(X , 0). b. Compute P(22.5 , X , 2.5). c. Compute P(22 # X # 3). d. For k satisfying 25 , k , k 1 4 , 5, compute P(k , X , k 1 4). 3. The error involved in making a certain measurement is a continuous rv X with pdf f (x) 5 e a. b. c. d. .09375(4 2 x 2) 22 # x # 2 0 otherwise Sketch the graph of f(x). Compute P(X . 0). Compute P(21 , X , 1). Compute P(X , 2.5 or X . .5). 4. Let X denote the vibratory stress (psi) on a wind turbine blade at a particular wind speed in a wind tunnel. The article “Blade Fatigue Life Assessment with Application to VAWTS” (J. of Solar Energy Engr., 1982: 107–111) proposes the Rayleigh distribution, with pdf x f(x; u) 5 • u 2 # e2x /(2u ) 2 2 0 x.0 otherwise as a model for the X distribution. a. Verify that f(x; u) is a legitimate pdf. b. Suppose u 5 100 (a value suggested by a graph in the article). What is the probability that X is at most 200? Less than 200? At least 200? c. What is the probability that X is between 100 and 200 (again assuming u 5 100)? d. Give an expression for P(X # x). 5. A college professor never finishes his lecture before the end of the hour and always finishes his lectures within 2 min after the hour. Let X 5 the time that elapses between the end of the hour and the end of the lecture and suppose the pdf of X is f(x) 5 e kx 2 0 # x # 2 0 otherwise a. Find the value of k and draw the corresponding density curve. [Hint: Total area under the graph of f(x) is 1.] b. What is the probability that the lecture ends within 1 min of the end of the hour? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.2 Cumulative Distribution Functions and Expected Values c. What is the probability that the lecture continues beyond the hour for between 60 and 90 sec? d. What is the probability that the lecture continues for at least 90 sec beyond the end of the hour? 6. The actual tracking weight of a stereo cartridge that is set to track at 3 g on a particular changer can be regarded as a continuous rv X with pdf 1 y 25 143 0#y,5 1 f( y) 5 e 2 2 y 5 # y # 10 5 25 0 y , 0 or y . 10 a. Sketch a graph of the pdf of Y. ` k[1 2 (x 2 3)2] 2 # x # 4 f(x) 5 e 0 otherwise a. Sketch the graph of f(x). b. Find the value of k. c. What is the probability that the actual tracking weight is greater than the prescribed weight? d. What is the probability that the actual weight is within .25 g of the prescribed weight? e. What is the probability that the actual weight differs from the prescribed weight by more than .5 g? 7. The time X (min) for a lab assistant to prepare the equipment for a certain experiment is believed to have a uniform distribution with A 5 25 and B 5 35. a. Determine the pdf of X and sketch the corresponding density curve. b. What is the probability that preparation time exceeds 33 min? c. What is the probability that preparation time is within 2 min of the mean time? [Hint: Identify m from the graph of f(x).] d. For any a such that 25 , a , a 1 2 , 35, what is the probability that preparation time is between a and a 1 2 min? 8. In commuting to work, a professor must first get on a bus near her house and then transfer to a second bus. If the waiting time (in minutes) at each stop has a uniform distribution with A 5 0 and B 5 5, then it can be shown that the total waiting time Y has the pdf b. Verify that 3 f( y) dy 5 1. 2` c. What is the probability that total waiting time is at most 3 min? d. What is the probability that total waiting time is at most 8 min? e. What is the probability that total waiting time is between 3 and 8 min? f. What is the probability that total waiting time is either less than 2 min or more than 6 min? 9. Consider again the pdf of X 5 time headway given in Example 4.5. What is the probability that time headway is a. At most 6 sec? b. More than 6 sec? At least 6 sec? c. Between 5 and 6 sec? 10. A family of pdf’s that has been used to approximate the distribution of income, city population size, and size of firms is the Pareto family. The family has two parameters, k and u, both . 0, and the pdf is k # uk x$u f(x; k, u) 5 u x k11 0 x,u a. Sketch the graph of f(x; k, u). b. Verify that the total area under the graph equals 1. c. If the rv X has pdf f (x; k, u), for any fixed b . u, obtain an expression for P(X # b). d. For u , a , b, obtain an expression for the probability P(a # X # b). 4.2 Cumulative Distribution Functions and Expected Values Several of the most important concepts introduced in the study of discrete distributions also play an important role for continuous distributions. Definitions analogous to those in Chapter 3 involve replacing summation by integration. The Cumulative Distribution Function The cumulative distribution function (cdf) F(x) for a discrete rv X gives, for any specified number x, the probability P(X # x). It is obtained by summing the pmf p(y) over all possible values y satisfying y # x. The cdf of a continuous rv gives the same probabilities P(X # x) and is obtained by integrating the pdf f(y) between the limits 2` and x. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 144 CHAPTER 4 Continuous Random Variables and Probability Distributions DEFINITION The cumulative distribution function F(x) for a continuous rv X is defined for every number x by x F(x) 5 P(X # x) 5 3 f( y) dy 2` For each x, F(x) is the area under the density curve to the left of x. This is illustrated in Figure 4.5, where F(x) increases smoothly as x increases. f (x) F (x) 1 F(8) F(8) .5 x 5 8 5 Figure 4.5 Example 4.6 x 10 8 10 A pdf and associated cdf Let X, the thickness of a certain metal sheet, have a uniform distribution on [A, B]. The density function is shown in Figure 4.6. For x , A, F(x) 5 0, since there is no area under the graph of the density function to the left of such an x. For x $ B, F(x) 5 1, since all the area is accumulated to the left of such an x. Finally, for A # x # B, x x 1 1 # y5x x2A dy 5 y` 5 F(x) 5 3 f(y)dy 5 3 B2A B2A B2A y5A 2` A f (x) f (x) Shaded area F(x) 1 B A 1 B A A B Figure 4.6 x A x B The pdf for a uniform distribution The entire cdf is 0 x,A x2A A#x,B F(x) 5 μ B2A 1 x$B The graph of this cdf appears in Figure 4.7. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.2 Cumulative Distribution Functions and Expected Values 145 F (x) 1 A Figure 4.7 x B ■ The cdf for a uniform distribution Using F (x ) to Compute Probabilities The importance of the cdf here, just as for discrete rv’s, is that probabilities of various intervals can be computed from a formula for or table of F(x). PROPOSITION Let X be a continuous rv with pdf f (x) and cdf F(x). Then for any number a, P(X . a) 5 1 2 F(a) and for any two numbers a and b with a , b, P(a # X # b) 5 F(b) 2 F(a) Figure 4.8 illustrates the second part of this proposition; the desired probability is the shaded area under the density curve between a and b, and it equals the difference between the two shaded cumulative areas. This is different from what is appropriate for a discrete integer valued random variable (e.g., binomial or Poisson): P(a # X # b) 5 F(b) 2 F(a 2 1) when a and b are integers. f (x) a b Figure 4.8 Example 4.7 b a Computing P(a # X # b) from cumulative probabilities Suppose the pdf of the magnitude X of a dynamic load on a bridge (in newtons) is given by 1 3 1 x 0#x#2 f(x) 5 • 8 8 0 otherwise For any number x between 0 and 2, x x 1 3 x 3 2 F(x) 5 3 f( y) dy 5 3 a 1 yb dy 5 1 x 8 8 8 16 2` 0 Thus 0 F(x) 5 d x,0 3 2 x 1 x 0#x#2 8 16 1 2,x Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 146 CHAPTER 4 Continuous Random Variables and Probability Distributions The graphs of f(x) and F(x) are shown in Figure 4.9. The probability that the load is between 1 and 1.5 is P(1 # X # 1.5) 5 F(1.5) 2 F(1) 1 3 1 3 5 c (1.5) 1 (1.5)2 d 2 c (1) 1 (1)2 d 8 16 8 16 19 5 5 .297 64 The probability that the load exceeds 1 is 1 3 P(X . 1) 5 1 2 P(X # 1) 5 1 2 F(1) 5 1 2 c (1) 1 (1)2 d 8 16 11 5 5 .688 16 f (x) F (x) 1 7 8 1 8 x 0 2 Figure 4.9 x 2 The pdf and cdf for Example 4.7 ■ Once the cdf has been obtained, any probability involving X can easily be calculated without any further integration. Obtaining f (x ) from F (x ) For X discrete, the pmf is obtained from the cdf by taking the difference between two F(x) values. The continuous analog of a difference is a derivative. The following result is a consequence of the Fundamental Theorem of Calculus. PROPOSITION If X is a continuous rv with pdf f(x) and cdf F(x), then at every x at which the derivative F r(x) exists, F r(x) 5 f (x). Example 4.8 When X has a uniform distribution, F(x) is differentiable except at x 5 A and x 5 B, where the graph of F(x) has sharp corners. Since F(x) 5 0 for x , A and F(x) 5 1 for x . B, F r(x) 5 0 5 f(x) for such x. For A , x , B, (Example 4.6 continued) F r(x) 5 d x2A 1 a b 5 5 f(x) dx B 2 A B2A ■ Percentiles of a Continuous Distribution When we say that an individual’s test score was at the 85th percentile of the population, we mean that 85% of all population scores were below that score and 15% were above. Similarly, the 40th percentile is the score that exceeds 40% of all scores and is exceeded by 60% of all scores. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.2 Cumulative Distribution Functions and Expected Values DEFINITION 147 Let p be a number between 0 and 1. The (100p)th percentile of the distribution of a continuous rv X, denoted by h(p), is defined by h(p) p 5 F(h(p)) 5 3 (4.2) f( y) dy 2` According to Expression (4.2), h(p) is that value on the measurement axis such that 100p% of the area under the graph of f(x) lies to the left of h(p) and 100(1 2 p)% lies to the right. Thus h(.75), the 75th percentile, is such that the area under the graph of f(x) to the left of h(.75) is .75. Figure 4.10 illustrates the definition. f (x) Shaded area p F(x) 1 p F( ( p)) ( p) Figure 4.10 Example 4.9 (p) x The (100p)th percentile of a continuous distribution The distribution of the amount of gravel (in tons) sold by a particular construction supply company in a given week is a continuous rv X with pdf 3 (1 2 x 2) 0 # x # 1 f (x) 5 • 2 0 otherwise The cdf of sales for any x between 0 and 1 is x y5x 3 3 y3 3 x3 F(x) 5 3 (1 2 y2) dy 5 a y 2 b ` 5 ax 2 b 2 2 3 2 3 y50 0 The graphs of both f(x) and F(x) appear in Figure 4.11. The (100p)th percentile of this distribution satisfies the equation p 5 F(h(p)) 5 3 (h(p))3 ch(p) 2 d 2 3 that is, (h(p))3 2 3h(p) 1 2p 5 0 For the 50th percentile, p 5 .5, and the equation to be solved is h3 2 3h 1 1 5 0; the solution is h 5 h(.5) 5 .347. If the distribution remains the same from week to week, then in the long run 50% of all weeks will result in sales of less than .347 ton and 50% in more than .347 ton. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 148 CHAPTER 4 Continuous Random Variables and Probability Distributions f (x) F(x) 1.5 1 .5 0 1 x Figure 4.11 DEFINITION 0 .347 1 x ■ The pdf and cdf for Example 4.9 |, is the 50th percentile, The median of a continuous distribution, denoted by m | | so m satisfies .5 5 F(m). That is, half the area under the density curve is to the | and half is to the right of m |. left of m A continuous distribution whose pdf is symmetric—the graph of the pdf to the left of some point is a mirror image of the graph to the right of that point—has | equal to the point of symmetry, since half the area under the curve lies median m to either side of this point. Figure 4.12 gives several examples. The error in a measurement of a physical quantity is often assumed to have a symmetric distribution. f (x) f (x) f (x) x A ˜ x ˜ B Figure 4.12 x ˜ Medians of symmetric distributions Expected Values For a discrete random variable X, E(X) was obtained by summing x # p(x)over possible X values. Here we replace summation by integration and the pmf by the pdf to get a continuous weighted average. DEFINITION The expected or mean value of a continuous rvX with pdf f (x) is ` mX 5 E(X) 5 3 x # f (x) dx 2` Example 4.10 (Example 4.9 continued) The pdf of weekly gravel sales X was 3 (1 2 x 2) 0 # x # 1 f (x) 5 u 2 0 otherwise Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.2 Cumulative Distribution Functions and Expected Values 149 so ` E(X) 5 3 x # 1 f(x) dx 5 3 x 0 2` # 3 (1 2 x 2) dx 2 3 3 x2 x 4 x51 3 (x 2 x 3) dx 5 a 2 b` 5 3 2 0 2 2 4 8 x50 1 5 ■ When the pdf f(x) specifies a model for the distribution of values in a numerical population, then m is the population mean, which is the most frequently used measure of population location or center. Often we wish to compute the expected value of some function h(X) of the rv X. If we think of h(X) as a new rv Y, techniques from mathematical statistics can be used to derive the pdf of Y, and E(Y) can then be computed from the definition. Fortunately, as in the discrete case, there is an easier way to compute E[h(X)]. PROPOSITION If X is a continuous rv with pdf f(x) and h(X) is any function of X, then ` E[h(X)] 5 mh(X) 5 3 h(x) # f(x) dx 2` Example 4.11 Two species are competing in a region for control of a limited amount of a certain resource. Let X 5 the proportion of the resource controlled by species 1 and suppose X has pdf f(x) 5 e 1 0#x#1 0 otherwise which is a uniform distribution on [0, 1]. (In her book Ecological Diversity, E. C. Pielou calls this the “broken-stick” model for resource allocation, since it is analogous to breaking a stick at a randomly chosen point.) Then the species that controls the majority of this resource controls the amount h(X) 5 max (X, 1 2 X) 5 μ 12X if 0 # X , X if 1 2 1 #X#1 2 The expected amount controlled by the species having majority control is then ` E[h(X)] 5 3 1 max(x, 1 2 x) # f(x) dx 5 3 max(x, 1 2 x) # 1 dx 0 2` 1/2 1 3 5 3 (1 2 x) # 1 dx 1 3 x # 1 dx 5 4 0 1/2 ■ For h(X), a linear function, E[h(X)] 5 E(aX 1 b) 5 aE(X) 1 b. In the discrete case, the variance of X was defined as the expected squared deviation from m and was calculated by summation. Here again integration replaces summation. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 150 Continuous Random Variables and Probability Distributions CHAPTER 4 DEFINITION The variance of a continuous random variable X with pdf f(x) and mean value m is ` sX2 5 V(X) 5 3 (x 2 m)2 # f(x)dx 5 E[(X 2 m)2] 2` The standard deviation (SD) of X is sX 5 2V(X). The variance and standard deviation give quantitative measures of how much spread there is in the distribution or population of x values. Again s is roughly the size of a typical deviation from m. Computation of s2 is facilitated by using the same shortcut formula employed in the discrete case. V(X) 5 E(X 2) 2 [E(X)]2 PROPOSITION Example 4.12 (Example 4.10 continued) For X 5 weekly gravel sales, we computed E(X) 5 38. Since ` 1 3 E(X 2) 5 3 x 2 # f(x) dx 5 3 x 2 # (1 2 x 2) dx 2 0 2` 1 3 1 5 3 (x 2 2 x 4) dx 5 2 5 0 V(X) 5 1 3 2 19 2 a b 5 5 .059 5 8 320 and sX 5 .244 ■ When h(X) 5 aX 1 b, the expected value and variance of h(X) satisfy the same properties as in the discrete case: E[h(X)] 5 am 1 b and V[h(X)] 5 a 2 # s2. EXERCISES Section 4.2 (11–27) 11. Let X denote the amount of time a book on two-hour reserve is actually checked out, and suppose the cdf is 12. The cdf for X (5 measurement error) of Exercise 3 is 0 x , 22 3 x3 1 a4x 2 b 22 # x , 2 F(x) 5 d 1 2 32 3 1 2#x 0 x,0 x2 0#x,2 F(x) 5 d 4 1 2#x Use the cdf to obtain the following: a. P(X # 1) b. P(.5 # X # 1) c. P(X . 1.5) | [solve .5 5 F(m |)] d. The median checkout duration m e. F r(x) to obtain the density function f(x) f. E(X) g. V(X) and sX h. If the borrower is charged an amount h(X ) 5 X 2 when checkout duration is X, compute the expected charge E[h(X)]. a. b. c. d. Compute P(X , 0). Compute P(21 , X , 1). Compute P(.5 , X). Verify that f(x) is as given in Exercise 3 by obtaining F r(x). | 5 0. e. Verify that m 13. Example 4.5 introduced the concept of time headway in traffic flow and proposed a particular distribution for X 5 the headway between two randomly selected consecutive cars (sec). Suppose that in a different traffic environment, the distribution of time headway has the form Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.2 Cumulative Distribution Functions and Expected Values k x.1 f(x) 5 • x 4 0 x#1 a. Determine the value of k for which f(x) is a legitimate pdf. b. Obtain the cumulative distribution function. c. Use the cdf from (b) to determine the probability that headway exceeds 2 sec and also the probability that headway is between 2 and 3 sec. d. Obtain the mean value of headway and the standard deviation of headway. e. What is the probability that headway is within 1 standard deviation of the mean value? 14. The article “Modeling Sediment and Water Column Interactions for Hydrophobic Pollutants” (Water Research, 1984: 1169–1174) suggests the uniform distribution on the interval (7.5, 20) as a model for depth (cm) of the bioturbation layer in sediment in a certain region. a. What are the mean and variance of depth? b. What is the cdf of depth? c. What is the probability that observed depth is at most 10? Between 10 and 15? d. What is the probability that the observed depth is within 1 standard deviation of the mean value? Within 2 standard deviations? 15. Let X denote the amount of space occupied by an article placed in a 1-ft3 packing container. The pdf of X is f(x) 5 e 90x 8(1 2 x) 0 , x , 1 0 otherwise a. Graph the pdf. Then obtain the cdf of X and graph it. b. What is P(X # .5) [i.e., F(.5)]? c. Using the cdf from (a), what is P(.25 , X # .5)? What is P(.25 # X # .5)? d. What is the 75th percentile of the distribution? e. Compute E(X) and sX. f. What is the probability that X is more than 1 standard deviation from its mean value? 16. Answer parts (a)–(f) of Exercise 15 with X 5 lecture time past the hour given in Exercise 5. 17. Let X have a uniform distribution on the interval [A, B]. a. Obtain an expression for the (100p)th percentile. b. Compute E(X), V(X), and sX. c. For n, a positive integer, compute E(X n). 18. Let X denote the voltage at the output of a microphone, and suppose that X has a uniform distribution on the interval from 21 to 1. The voltage is processed by a “hard limiter” with cutoff values 2.5 and .5, so the limiter output is a random variable Y related to X by Y 5 X if |X| # .5, Y 5 .5 if X . .5, and Y 5 2.5 if X , 2.5. a. What is P(Y 5 .5)? b. Obtain the cumulative distribution function of Y and graph it. 151 19. Let X be a continuous rv with cdf 0 x#0 4 x F(x) 5 μ c1 1 lna b d 0 , x # 4 x 4 1 x.4 [This type of cdf is suggested in the article “Variability in Measured Bedload-Transport Rates” (Water Resources Bull., 1985: 39–48) as a model for a certain hydrologic variable.] What is a. P(X # 1)? b. P(1 # X # 3)? c. The pdf of X? 20. Consider the pdf for total waiting time Y for two buses 1 y 0#y,5 25 1 f ( y) 5 e 2 2 y 5 # y # 10 5 25 0 otherwise introduced in Exercise 8. a. Compute and sketch the cdf of Y. [Hint: Consider separately 0 # y , 5 and 5 # y # 10 in computing F(y). A graph of the pdf should be helpful.] b. Obtain an expression for the (100p)th percentile. [Hint: Consider separately 0 , p , .5 and .5 , p , 1.] c. Compute E(Y ) and V(Y). How do these compare with the expected waiting time and variance for a single bus when the time is uniformly distributed on [0, 5]? 21. An ecologist wishes to mark off a circular sampling region having radius 10 m. However, the radius of the resulting region is actually a random variable R with pdf f(r) 5 u 3 [1 2 (10 2 r)2] 9 # r # 11 4 0 otherwise What is the expected area of the resulting circular region? 22. The weekly demand for propane gas (in 1000s of gallons) from a particular facility is an rv X with pdf u 2a1 2 x 2 b 1 f(x) 5 0 1#x#2 otherwise a. Compute the cdf of X. b. Obtain an expression for the (100p)th percentile. What is |? the value of m c. Compute E(X) and V(X). d. If 1.5 thousand gallons are in stock at the beginning of the week and no new supply is due in during the week, how much of the 1.5 thousand gallons is expected to be left at the end of the week? [Hint: Let h(x) 5 amount left when demand 5 x.] Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 152 CHAPTER 4 Continuous Random Variables and Probability Distributions 23. If the temperature at which a certain compound melts is a random variable with mean value 1208C and standard deviation 28 C, what are the mean temperature and standard deviation measured in 8F? [Hint: 8F 5 1.88 C 1 32.] Although X is a discrete random variable, suppose its distribution is quite well approximated by a continuous distribution with pdf f(x) 5 k(1 1 x/2.5)27 for x $ 0. a. What is the value of k? b. Graph the pdf of X. c. What are the expected value and standard deviation of total medical expenses? d. This individual is covered by an insurance plan that entails a $500 deductible provision (so the first $500 worth of expenses are paid by the individual). Then the plan will pay 80% of any additional expenses exceeding $500, and the maximum payment by the individual (including the deductible amount) is $2500. Let Y denote the amount of this individual’s medical expenses paid by the insurance company. What is the expected value of Y? [Hint: First figure out what value of X corresponds to the maximum out-of-pocket expense of $2500. Then write an expression for Y as a function of X (which involves several different pieces) and calculate the expected value of this function.] 24. Let X have the Pareto pdf f (x; k, u) 5 u k # uk x$u x k11 0 x,u introduced in Exercise 10. a. If k . 1, compute E(X). b. What can you say about E(X) if k 5 1? c. If k . 2, show that V(X) 5 ku2 (k 2 1)22 (k 2 2)21. d. If k 5 2, what can you say about V(X)? e. What conditions on k are necessary to ensure that E(X n) is finite? 25. Let X be the temperature in 8 C at which a certain chemical reaction takes place, and let Y be the temperature in 8 F (so Y 5 1.8X 1 32). |, show that a. If the median of the X distribution is m | 1.8m 1 32 is the median of the Y distribution. b. How is the 90th percentile of the Y distribution related to the 90th percentile of the X distribution? Verify your conjecture. c. More generally, if Y 5 aX 1 b, how is any particular percentile of the Y distribution related to the corresponding percentile of the X distribution? 26. Let X be the total medical expenses (in 1000s of dollars) incurred by a particular individual during a given year. 27. When a dart is thrown at a circular target, consider the location of the landing point relative to the bull’s eye. Let X be the angle in degrees measured from the horizontal, and assume that X is uniformly distributed on [0, 360]. Define Y to be the transformed variable Y 5 h(X) 5 (2p/360)X 2 p, so Y is the angle measured in radians and Y is between 2p and p. Obtain E(Y) and sY by first obtaining E(X) and sX, and then using the fact that h(X) is a linear function of X. 4.3 The Normal Distribution The normal distribution is the most important one in all of probability and statistics. Many numerical populations have distributions that can be fit very closely by an appropriate normal curve. Examples include heights, weights, and other physical characteristics (the famous 1903 Biometrika article “On the Laws of Inheritance in Man” discussed many examples of this sort), measurement errors in scientific experiments, anthropometric measurements on fossils, reaction times in psychological experiments, measurements of intelligence and aptitude, scores on various tests, and numerous economic measures and indicators. In addition, even when individual variables themselves are not normally distributed, sums and averages of the variables will under suitable conditions have approximately a normal distribution; this is the content of the Central Limit Theorem discussed in the next chapter. DEFINITION A continuous rv X is said to have a normal distribution with parameters m and s (or m and s2), where 2` , m , ` and 0 , s, if the pdf of X is f(x; m, s) 5 1 2 2 e2(x2m) /(2s ) 2` , x , ` 12ps (4.3) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 153 4.3 The Normal Distribution Again e denotes the base of the natural logarithm system and equals approximately 2.71828, and p represents the familiar mathematical constant with approximate value 3.14159. The statement that X is normally distributed with parameters m and s2 is often abbreviated X | N(m, s2). Clearly f(x; m, s) $ 0, but a somewhat complicated calculus argument must be used to verify that 冕 `2` f (x; m, s) dx 5 1. It can be shown that E(X) 5 m and V(X) 5 s2, so the parameters are the mean and the standard deviation of X. Figure 4.13 presents graphs of f (x; m, s) for several different (m, s) pairs. Each density curve is symmetric about m and bell-shaped, so the center of the bell (point of symmetry) is both the mean of the distribution and the median. The value of s is the distance from m to the inflection points of the curve (the points at which the curve changes from turning downward to turning upward). Large values of s yield graphs that are quite spread out about m, whereas small values of s yield graphs with a high peak above m and most of the area under the graph quite close to m. Thus a large s implies that a value of X far from m may well be observed, whereas such a value is quite unlikely when s is small. f(x) 0.09 0.08 0.07 0.06 = 100, = 5 0.05 0.04 0.03 = 80, 0.02 = 15 0.01 x 0.00 40 60 80 100 ␮ 120 Figure 4.13 distribution ␮ (b) (a) (a) Two different normal density curves (b) Visualizing m and s for a normal The Standard Normal Distribution The computation of P(a # X # b) when X is a normal rv with parameters m and s requires evaluating b 1 2(x2m)2/(2s2) dx 3 12ps e a (4.4) None of the standard integration techniques can be used to accomplish this. Instead, for m 5 0 and s 5 1, Expression (4.4) has been calculated using numerical techniques and tabulated for certain values of a and b. This table can also be used to compute probabilities for any other values of m and s under consideration. DEFINITION The normal distribution with parameter values m 5 0 and s 5 1 is called the standard normal distribution. A random variable having a standard normal distribution is called a standard normal random variable and will be denoted by Z. The pdf of Z is f(z; 0, 1) 5 1 2 e2z /2 12p 2` , z , ` Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 154 CHAPTER 4 Continuous Random Variables and Probability Distributions The graph of f(z; 0, 1) is called the standard normal (or zz) curve. Its inflection points are at 1 and 21. The cdf of Z is P(Z # z) 5 冮 f (y; 0, 1) dy, which 2` we will denote by (z). The standard normal distribution almost never serves as a model for a naturally arising population. Instead, it is a reference distribution from which information about other normal distributions can be obtained. Appendix Table A.3 gives (z) 5 P(Z # z), the area under the standard normal density curve to the left of z, for z 5 23.49, 23.48, c, 3.48, 3.49. Figure 4.14 illustrates the type of cumulative area (probability) tabulated in Table A.3. From this table, various other probabilities involving Z can be calculated. Shaded area (z) Standard normal (z) curve 0 Figure 4.14 Example 4.13 z Standard normal cumulative areas tabulated in Appendix Table A.3 Let’s determine the following standard normal probabilities: (a) P(Z # 1.25), (b) P(Z . 1.25), (c) P(Z # 21.25), and (d) P(2.38 # Z # 1.25). a. P(Z # 1.25) 5 (1.25), a probability that is tabulated in Appendix Table A.3 at the intersection of the row marked 1.2 and the column marked .05. The number there is .8944, so P(Z # 1.25) 5 .8944. Figure 4.15(a) illustrates this probability. Shaded area (1.25) 0 (a) Figure 4.15 z curve 1.25 z curve 0 (b) 1.25 Normal curve areas (probabilities) for Example 4.13 b. P(Z . 1.25) 5 1 2 P(Z # 1.25) 5 1 2 (1.25), the area under the z curve to the right of 1.25 (an upper-tail area). Then (1.25) 5 .8944 implies that P(Z . 1.25) 5 .1056. Since Z is a continuous rv, P(Z $ 1.25) 5 .1056. See Figure 4.15(b). c. P(Z # 21.25) 5 (21.25), a lower-tail area. Directly from Appendix Table A.3, (21.25) 5 .1056. By symmetry of the z curve, this is the same answer as in part (b). d. P(2.38 # Z # 1.25) is the area under the standard normal curve above the interval whose left endpoint is 2.38 and whose right endpoint is 1.25. From Section 4.2, if X is a continuous rv with cdf F(x), then P(a # X # b) 5 F(b) 2 F(a). Thus P(2.38 # Z # 1.25) 5 (1.25) 2 (2.38) 5 .8944 2 .3520 5 .5424. (See Figure 4.16.) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.3 The Normal Distribution 155 z curve .38 0 Figure 4.16 1.25 0 1.25 .38 0 P(2.38 # Z # 1.25) as the difference between two cumulative areas ■ Percentiles of the Standard Normal Distribution For any p between 0 and 1, Appendix Table A.3 can be used to obtain the (100p)th percentile of the standard normal distribution. Example 4.14 The 99th percentile of the standard normal distribution is that value on the horizontal axis such that the area under the z curve to the left of the value is .9900. Appendix Table A.3 gives for fixed z the area under the standard normal curve to the left of z, whereas here we have the area and want the value of z. This is the “inverse” problem to P(Z # z) 5 ? so the table is used in an inverse fashion: Find in the middle of the table .9900; the row and column in which it lies identify the 99th z percentile. Here .9901 lies at the intersection of the row marked 2.3 and column marked .03, so the 99th percentile is (approximately) z 5 2.33. (See Figure 4.17.) By symmetry, the first percentile is as far below 0 as the 99th is above 0, so equals 22.33 (1% lies below the first and also above the 99th). (See Figure 4.18.) Shaded area .9900 z curve 0 99th percentile Figure 4.17 Finding the 99th percentile z curve Shaded area .01 0 2.33 1st percentile Figure 4.18 2.33 99th percentile The relationship between the 1st and 99th percentiles ■ In general, the (100p)th percentile is identified by the row and column of Appendix Table A.3 in which the entry p is found (e.g., the 67th percentile is obtained by finding .6700 in the body of the table, which gives z 5 .44). If p does not appear, the number closest to it is often used, although linear interpolation gives a more accurate answer. For example, to find the 95th percentile, we look for .9500 inside the table. Although .9500 does not appear, both .9495 and .9505 do, corresponding to z 5 1.64 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 156 CHAPTER 4 Continuous Random Variables and Probability Distributions and 1.65, respectively. Since .9500 is halfway between the two probabilities that do appear, we will use 1.645 as the 95th percentile and 21.645 as the 5th percentile. zA Notation for z Critical Values In statistical inference, we will need the values on the horizontal z axis that capture certain small tail areas under the standard normal curve. Notation za will denote the value on the z axis for which a of the area under the z curve lies to the right of za . (See Figure 4.19.) For example, z.10 captures upper-tail area .10, and z.01 captures upper-tail area .01. Shaded area P(Z z curve z ) 0 z Figure 4.19 za notation Illustrated Since a of the area under the z curve lies to the right of za,1 2 a of the area lies to its left. Thus za is the 100(1 2 a)th percentile of the standard normal distribution. By symmetry the area under the standard normal curve to the left of 2za is also a. The zars are usually referred to as z critical values. Table 4.1 lists the most useful z percentiles and za values. Table 4.1 Standard Normal Percentiles and Critical Values Percentile a (tail area) za 5 100(1 2 a) th percentile Example 4.15 90 .1 1.28 95 .05 1.645 97.5 .025 1.96 99 .01 2.33 99.5 .005 2.58 99.9 .001 3.08 99.95 .0005 3.27 z.05 is the 100(1 2 .05)th 5 95th percentile of the standard normal distribution, so z.05 5 1.645 . The area under the standard normal curve to the left of 2z.05 is also .05. (See Figure 4.20.) z curve Shaded area .05 Shaded area .05 0 1.645 z.05 z.05 95th percentile 1.645 Figure 4.20 Finding z.05 ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.3 The Normal Distribution 157 Nonstandard Normal Distributions When X , N(m, s2), probabilities involving X are computed by “standardizing.” The standardized variable is (X 2 m)/s. Subtracting m shifts the mean from m to zero, and then dividing by s scales the variable so that the standard deviation is 1 rather than s. PROPOSITION If X has a normal distribution with mean m and standard deviation s, then X2m s Z5 has a standard normal distribution. Thus P(a # X # b) 5 Pa a2m b2m #Z# b s s 5 a P(X # a) 5 a a2m b s b2m a2m b 2 a b s s P(X $ b) 5 1 2 a b2m b s The key idea of the proposition is that by standardizing, any probability involving X can be expressed as a probability involving a standard normal rv Z, so that Appendix Table A.3 can be used. This is illustrated in Figure 4.21. The proposition can be proved by writing the cdf of Z 5 (X 2 m)/s as P(Z # z) 5 P(X # sz 1 m) 5 冮 sz1m f(x; m, s)dx 2` Using a result from calculus, this integral can be differentiated with respect to z to yield the desired pdf f (z; 0, 1). N( , 2) N(0, 1) Figure 4.21 Example 4.16 x 0 (x )/ Equality of nonstandard and standard normal curve areas The time that it takes a driver to react to the brake lights on a decelerating vehicle is critical in helping to avoid rear-end collisions. The article “Fast-Rise Brake Lamp as a Collision-Prevention Device” (Ergonomics, 1993: 391–395) suggests that reaction time for an in-traffic response to a brake signal from standard brake lights can be modeled with a normal distribution having mean value 1.25 sec and standard deviation of .46 sec. What is the probability that reaction time is Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 158 CHAPTER 4 Continuous Random Variables and Probability Distributions between 1.00 sec and 1.75 sec? If we let X denote reaction time, then standardizing gives 1.00 # X # 1.75 if and only if 1.00 2 1.25 X 2 1.25 1.75 2 1.25 # # .46 .46 .46 Thus 1.00 2 1.25 1.75 2 1.25 #Z# b .46 .46 5 P(2.54 # Z # 1.09) 5 (1.09) 2 (2.54) 5 .8621 2 .2946 5 .5675 P(1.00 # X # 1.75) 5 Pa Normal, 1.25, .46 P(1.00 X 1.75) z curve 1.25 1.00 0 1.75 Figure 4.22 .54 1.09 Normal curves for Example 4.16 This is illustrated in Figure 4.22. Similarly, if we view 2 sec as a critically long reaction time, the probability that actual reaction time will exceed this value is P(X . 2) 5 PaZ . 2 2 1.25 b 5 P(Z . 1.63) 5 1 2 (1.63) 5 .0516 .46 ■ Standardizing amounts to nothing more than calculating a distance from the mean value and then reexpressing the distance as some number of standard deviations. Thus, if m 5 100 and s 5 15, then x 5 130 corresponds to z 5 (130 2 100)/15 5 30/15 5 2.00. That is, 130 is 2 standard deviations above (to the right of) the mean value. Similarly, standardizing 85 gives (85 2 100)/15 5 21.00, so 85 is 1 standard deviation below the mean. The z table applies to any normal distribution provided that we think in terms of number of standard deviations away from the mean value. Example 4.17 The breakdown voltage of a randomly chosen diode of a particular type is known to be normally distributed. What is the probability that a diode’s breakdown voltage is within 1 standard deviation of its mean value? This question can be answered without knowing either m or s, as long as the distribution is known to be normal; the answer is the same for any normal distribution: P(X is within 1 standard deviation of its mean) 5 P(m 2 s # X # m 1 s) m2s2m m1s2m 5 Pa #Z# b s s 5 P(21.00 # Z # 1.00) 5 (1.00) 2 (21.00) 5 .6826 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.3 The Normal Distribution 159 The probability that X is within 2 standard deviations of its mean is P(22.00 # Z # 2.00) 5 .9544 and within 3 standard deviations of the mean is P(23.00 # Z # 3.00) 5 .9974. ■ The results of Example 4.17 are often reported in percentage form and referred to as the empirical rule (because empirical evidence has shown that histograms of real data can very frequently be approximated by normal curves). If the population distribution of a variable is (approximately) normal, then 1. Roughly 68% of the values are within 1 SD of the mean. 2. Roughly 95% of the values are within 2 SDs of the mean. 3. Roughly 99.7% of the values are within 3 SDs of the mean. It is indeed unusual to observe a value from a normal population that is much farther than 2 standard deviations from m. These results will be important in the development of hypothesis-testing procedures in later chapters. Percentiles of an Arbitrary Normal Distribution The (100p)th percentile of a normal distribution with mean m and standard deviation s is easily related to the (100p)th percentile of the standard normal distribution. PROPOSITION (100p)th percentile (100p)th for 5m1 c d #s for normal (m, s) standard normal Another way of saying this is that if z is the desired percentile for the standard normal distribution, then the desired percentile for the normal ( m, s) distribution is z standard deviations from m. Example 4.18 The amount of distilled water dispensed by a certain machine is normally distributed with mean value 64 oz and standard deviation .78 oz. What container size c will ensure that overflow occurs only .5% of the time? If X denotes the amount dispensed, the desired condition is that P(X . c) 5 .005, or, equivalently, that P(X # c) 5 .995. Thus c is the 99.5th percentile of the normal distribution with m 5 64 and s 5 .78. The 99.5th percentile of the standard normal distribution is 2.58, so c 5 h(.995) 5 64 1 (2.58)(.78) 5 64 1 2.0 5 66 oz This is illustrated in Figure 4.23. Shaded area .995 64 c 99.5th percentile 66.0 Figure 4.23 Distribution of amount dispensed for Example 4.18 ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 160 CHAPTER 4 Continuous Random Variables and Probability Distributions The Normal Distribution and Discrete Populations The normal distribution is often used as an approximation to the distribution of values in a discrete population. In such situations, extra care should be taken to ensure that probabilities are computed in an accurate manner. Example 4.19 IQ in a particular population (as measured by a standard test) is known to be approximately normally distributed with m 5 100 and s 5 15. What is the probability that a randomly selected individual has an IQ of at least 125? Letting X 5 the IQ of a randomly chosen person, we wish P(X $ 125). The temptation here is to standardize X $ 125 as in previous examples. However, the IQ population distribution is actually discrete, since IQs are integer-valued. So the normal curve is an approximation to a discrete probability histogram, as pictured in Figure 4.24. The rectangles of the histogram are centered at integers, so IQs of at least 125 correspond to rectangles beginning at 124.5, as shaded in Figure 4.24. Thus we really want the area under the approximating normal curve to the right of 124.5. Standardizing this value gives P(Z $ 1.63) 5 .0516, whereas standardizing 125 results in P(Z $ 1.67) 5 .0475. The difference is not great, but the answer .0516 is more accurate. Similarly, P(X 5 125) would be approximated by the area between 124.5 and 125.5, since the area under the normal curve above the single value 125 is zero. 125 Figure 4.24 A normal approximation to a discrete distribution ■ The correction for discreteness of the underlying distribution in Example 4.19 is often called a continuity correction. It is useful in the following application of the normal distribution to the computation of binomial probabilities. Approximating the Binomial Distribution Recall that the mean value and standard deviation of a binomial random variable X are mX 5 np and sX 5 1npq, respectively. Figure 4.25 displays a binomial probability histogram for the binomial distribution with n 5 20, p 5 .6, for which m 5 20(.6) 5 12 and s 5 120(.6)(.4) 5 2.19. A normal curve with this m and s has been superimposed on the probability histogram. Although the probability histogram is a bit skewed (because p 2 .5), the normal curve gives a very good approximation, especially in the middle part of the picture. The area of any rectangle (probability of any particular X value) except those in the extreme tails can be accurately approximated by the corresponding normal curve area. For example, P(X 5 10) 5 B(10; 20, .6) 2 B(9; 20, .6) 5 .117, whereas the area under the normal curve between 9.5 and 10.5 is P(21.14 # Z # 2.68) 5 .1212. More generally, as long as the binomial probability histogram is not too skewed, binomial probabilities can be well approximated by normal curve areas. It is then customary to say that X has approximately a normal distribution. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.3 The Normal Distribution 161 Normal curve, μ 12, σ 2.19 .20 .15 .10 .05 0 2 4 6 8 10 12 14 16 18 20 Figure 4.25 Binomial probability histogram for n 5 20, p 5 .6 with normal approximation curve superimposed PROPOSITION Let X be a binomial rv based on n trials with success probability p. Then if the binomial probability histogram is not too skewed, X has approximately a normal distribution with m 5 np and s 5 1npq. In particular, for x 5 a possible value of X, P(X # x) 5 B(x, n, p) < a area under the normal curve b to the left of x 1 .5 x 1 .5 2 np 5 a b 1npq In practice, the approximation is adequate provided that both np $ 10 and nq $ 10, since there is then enough symmetry in the underlying binomial distribution. A direct proof of this result is quite difficult. In the next chapter we’ll see that it is a consequence of a more general result called the Central Limit Theorem. In all honesty, this approximation is not so important for probability calculation as it once was. This is because software can now calculate binomial probabilities exactly for quite large values of n. Example 4.20 Suppose that 25% of all students at a large public university receive financial aid. Let X be the number of students in a random sample of size 50 who receive financial aid, so that p 5 .25. Then m 5 12.5 and s 5 3.06. Since np 5 50(.25) 5 12.5 $ 10 and nq 5 37.5 $ 10, the approximation can safely be applied. The probability that at most 10 students receive aid is 10 1 .5 2 12.5 b 3.06 5 (2.65) 5 .2578 P(X # 10) 5 B(10; 50, .25) < a Similarly, the probability that between 5 and 15 (inclusive) of the selected students receive aid is P(5 # X # 15) 5 B(15; 50, .25) 2 B(4; 50, .25) 15.5 2 12.5 4.5 2 12.5 < a b 2 a b 5 .8320 3.06 3.06 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 162 CHAPTER 4 Continuous Random Variables and Probability Distributions The exact probabilities are .2622 and .8348, respectively, so the approximations are quite good. In the last calculation, the probability P(5 # X # 15) is being approximated by the area under the normal curve between 4.5 and 15.5—the continuity correction is used for both the upper and lower limits. ■ When the objective of our investigation is to make an inference about a population proportion p, interest will focus on the sample proportion of successes X/n rather than on X itself. Because this proportion is just X multiplied by the constant 1/n, it will also have approximately a normal distribution (with mean m 5 p and standard deviation s 5 1pq/n) provided that both np $ 10 and nq $ 10. This normal approximation is the basis for several inferential procedures to be discussed in later chapters. EXERCISES Section 4.3 (28–58) 28. Let Z be a standard normal random variable and calculate the following probabilities, drawing pictures wherever appropriate. a. P(0 # Z # 2.17) b. P(0 # Z # 1) c. P(22.50 # Z # 0) d. P(22.50 # Z # 2.50) e. P(Z # 1.37) f. P(21.75 # Z) g. P(21.50 # Z # 2.00) h. P(1.37 # Z # 2.50) i. P(1.50 # Z) j. P( u Z u # 2.50) deviation 1.75 km/h is postulated. Consider randomly selecting a single such moped. a. What is the probability that maximum speed is at most 50 km/h? b. What is the probability that maximum speed is at least 48 km/h? c. What is the probability that maximum speed differs from the mean value by at most 1.5 standard deviations? 29. In each case, determine the value of the constant c that makes the probability statement correct. a. (c) 5 .9838 b. P(0 # Z # c) 5 .291 c. P(c # Z) 5 .121 d. P(2c # Z # c) 5 .668 e. P(c # u Z u) 5 .016 34. The article “Reliability of Domestic-Waste Biofilm Reactors” (J. of Envir. Engr., 1995: 785–790) suggests that substrate concentration (mg/cm3) of influent to a reactor is normally distributed with m 5 .30 and s 5 .06. a. What is the probability that the concentration exceeds .25? b. What is the probability that the concentration is at most .10? c. How would you characterize the largest 5% of all concentration values? 30. Find the following percentiles for the standard normal distribution. Interpolate where appropriate. a. 91st b. 9th c. 75th d. 25th e. 6th 31. Determine za for the following: a. a 5 .0055 b. a 5 .09 c. a 5 .663 32. Suppose the force acting on a column that helps to support a building is a normally distributed random variable X with mean value 15.0 kips and standard deviation 1.25 kips. Compute the following probabilities by standardizing and then using Table A.3. a. P(X # 15) b. P(X # 17.5) c. P(X $ 10) d. P(14 # X # 18) e. P(u X 2 15 u # 3) 33. Mopeds (small motorcycles with an engine capacity below 50 cm3) are very popular in Europe because of their mobility, ease of operation, and low cost. The article “Procedure to Verify the Maximum Speed of Automatic Transmission Mopeds in Periodic Motor Vehicle Inspections” (J. of Automobile Engr., 2008: 1615–1623) described a rolling bench test for determining maximum vehicle speed. A normal distribution with mean value 46.8 km/h and standard 35. Suppose the diameter at breast height (in.) of trees of a certain type is normally distributed with m 5 8.8 and s 5 2.8, as suggested in the article “Simulating a Harvester-Forwarder Softwood Thinning” (Forest Products J., May 1997: 36–41). a. What is the probability that the diameter of a randomly selected tree will be at least 10 in.? Will exceed 10 in.? b. What is the probability that the diameter of a randomly selected tree will exceed 20 in.? c. What is the probability that the diameter of a randomly selected tree will be between 5 and 10 in.? d. What value c is such that the interval (8.8 2 c, 8.8 1 c) includes 98% of all diameter values? e. If four trees are independently selected, what is the probability that at least one has a diameter exceeding 10 in.? 36. Spray drift is a constant concern for pesticide applicators and agricultural producers. The inverse relationship between droplet size and drift potential is well known. The Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.3 The Normal Distribution paper “Effects of 2,4-D Formulation and Quinclorac on Spray Droplet Size and Deposition” (Weed Technology, 2005: 1030–1036) investigated the effects of herbicide formulation on spray atomization. A figure in the paper suggested the normal distribution with mean 1050 mm and standard deviation 150 mm was a reasonable model for droplet size for water (the “control treatment”) sprayed through a 760 ml/min nozzle. a. What is the probability that the size of a single droplet is less than 1500 mm? At least 1000 mm? b. What is the probability that the size of a single droplet is between 1000 and 1500 mm? c. How would you characterize the smallest 2% of all droplets? d. If the sizes of five independently selected droplets are measured, what is the probability that at least one exceeds 1500 mm? 37. Suppose that blood chloride concentration (mmol/L) has a normal distribution with mean 104 and standard deviation 5 (information in the article “Mathematical Model of Chloride Concentration in Human Blood,” J. of Med. Engr. and Tech., 2006: 25–30, including a normal probability plot as described in Section 4.6, supports this assumption). a. What is the probability that chloride concentration equals 105? Is less than 105? Is at most 105? b. What is the probability that chloride concentration differs from the mean by more than 1 standard deviation? Does this probability depend on the values of m and s? c. How would you characterize the most extreme .1% of chloride concentration values? 38. There are two machines available for cutting corks intended for use in wine bottles. The first produces corks with diameters that are normally distributed with mean 3 cm and standard deviation .1 cm. The second machine produces corks with diameters that have a normal distribution with mean 3.04 cm and standard deviation .02 cm. Acceptable corks have diameters between 2.9 cm and 3.1 cm. Which machine is more likely to produce an acceptable cork? 39. a. If a normal distribution has m 5 30 and s 5 5, what is the 91st percentile of the distribution? b. What is the 6th percentile of the distribution? c. The width of a line etched on an integrated circuit chip is normally distributed with mean 3.000 mm and standard deviation .140. What width value separates the widest 10% of all such lines from the other 90%? 40. The article “Monte Carlo Simulation—Tool for Better Understanding of LRFD” (J. of Structural Engr., 1993: 1586–1599) suggests that yield strength (ksi) for A36 grade steel is normally distributed with m 5 43 and s 5 4.5. a. What is the probability that yield strength is at most 40? Greater than 60? b. What yield strength value separates the strongest 75% from the others? 163 41. The automatic opening device of a military cargo parachute has been designed to open when the parachute is 200 m above the ground. Suppose opening altitude actually has a normal distribution with mean value 200 m and standard deviation 30 m. Equipment damage will occur if the parachute opens at an altitude of less than 100 m. What is the probability that there is equipment damage to the payload of at least one of five independently dropped parachutes? 42. The temperature reading from a thermocouple placed in a constant-temperature medium is normally distributed with mean m, the actual temperature of the medium, and standard deviation s. What would the value of s have to be to ensure that 95% of all readings are within .18 of m? 43. The distribution of resistance for resistors of a certain type is known to be normal, with 10% of all resistors having a resistance exceeding 10.256 ohms and 5% having a resistance smaller than 9.671 ohms. What are the mean value and standard deviation of the resistance distribution? 44. If bolt thread length is normally distributed, what is the probability that the thread length of a randomly selected bolt is a. Within 1.5 SDs of its mean value? b. Farther than 2.5 SDs from its mean value? c. Between 1 and 2 SDs from its mean value? 45. A machine that produces ball bearings has initially been set so that the true average diameter of the bearings it produces is .500 in. A bearing is acceptable if its diameter is within .004 in. of this target value. Suppose, however, that the setting has changed during the course of production, so that the bearings have normally distributed diameters with mean value .499 in. and standard deviation .002 in. What percentage of the bearings produced will not be acceptable? 46. The Rockwell hardness of a metal is determined by impressing a hardened point into the surface of the metal and then measuring the depth of penetration of the point. Suppose the Rockwell hardness of a particular alloy is normally distributed with mean 70 and standard deviation 3. (Rockwell hardness is measured on a continuous scale.) a. If a specimen is acceptable only if its hardness is between 67 and 75, what is the probability that a randomly chosen specimen has an acceptable hardness? b. If the acceptable range of hardness is (70 2 c, 70 1 c), for what value of c would 95% of all specimens have acceptable hardness? c. If the acceptable range is as in part (a) and the hardness of each of ten randomly selected specimens is independently determined, what is the expected number of acceptable specimens among the ten? d. What is the probability that at most eight of ten independently selected specimens have a hardness of less than Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 164 CHAPTER 4 Continuous Random Variables and Probability Distributions 73.84? [Hint: Y 5 the number among the ten specimens with hardness less than 73.84 is a binomial variable; what is p?] 47. The weight distribution of parcels sent in a certain manner is normal with mean value 12 lb and standard deviation 3.5 lb. The parcel service wishes to establish a weight value c beyond which there will be a surcharge. What value of c is such that 99% of all parcels are at least 1 lb under the surcharge weight? 48. Suppose Appendix Table A.3 contained (z) only for z $ 0. Explain how you could still compute a. P(21.72 # Z # 2.55) b. P(21.72 # Z # .55) Is it necessary to tabulate (z) for z negative? What property of the standard normal curve justifies your answer? 49. Consider babies born in the “normal” range of 37–43 weeks gestational age. Extensive data supports the assumption that for such babies born in the United States, birth weight is normally distributed with mean 3432 g and standard deviation 482 g. [The article “Are Babies Normal?” (The American Statistician, 1999: 298–302) analyzed data from a particular year; for a sensible choice of class intervals, a histogram did not look at all normal, but after further investigations it was determined that this was due to some hospitals measuring weight in grams and others measuring to the nearest ounce and then converting to grams. A modified choice of class intervals that allowed for this gave a histogram that was well described by a normal distribution.] a. What is the probability that the birth weight of a randomly selected baby of this type exceeds 4000 g? Is between 3000 and 4000 g? b. What is the probability that the birth weight of a randomly selected baby of this type is either less than 2000 g or greater than 5000 g? c. What is the probability that the birth weight of a randomly selected baby of this type exceeds 7 lb? d. How would you characterize the most extreme .1% of all birth weights? e. If X is a random variable with a normal distribution and a is a numerical constant (a 2 0), then Y 5 aX also has a normal distribution. Use this to determine the distribution of birth weight expressed in pounds (shape, mean, and standard deviation), and then recalculate the probability from part (c). How does this compare to your previous answer? 50. In response to concerns about nutritional contents of fast foods, McDonald’s has announced that it will use a new cooking oil for its french fries that will decrease substantially trans fatty acid levels and increase the amount of more beneficial polyunsaturated fat. The company claims that 97 out of 100 people cannot detect a difference in taste between the new and old oils. Assuming that this figure is correct (as a long-run proportion), what is the approximate probability that in a random sample of 1000 individuals who have purchased fries at McDonald’s, a. At least 40 can taste the difference between the two oils? b. At most 5% can taste the difference between the two oils? 51. Chebyshev’s inequality, (see Exercise 44, Chapter 3), is valid for continuous as well as discrete distributions. It states that for any number k satisfying k $ 1, P(u X 2 m u $ ks) # 1/k2 (see Exercise 44 in Chapter 3 for an interpretation). Obtain this probability in the case of a normal distribution for k 5 1, 2, and 3, and compare to the upper bound. 52. Let X denote the number of flaws along a 100-m reel of magnetic tape (an integer-valued variable). Suppose X has approximately a normal distribution with m 5 25 and s 5 5. Use the continuity correction to calculate the probability that the number of flaws is a. Between 20 and 30, inclusive. b. At most 30. Less than 30. 53. Let X have a binomial distribution with parameters n 5 25 and p. Calculate each of the following probabilities using the normal approximation (with the continuity correction) for the cases p 5 .5, .6, and .8 and compare to the exact probabilities calculated from Appendix Table A.1. a. P(15 # X # 20) b. P(X # 15) c. P(20 # X) 54. Suppose that 10% of all steel shafts produced by a certain process are nonconforming but can be reworked (rather than having to be scrapped). Consider a random sample of 200 shafts, and let X denote the number among these that are nonconforming and can be reworked. What is the (approximate) probability that X is a. At most 30? b. Less than 30? c. Between 15 and 25 (inclusive)? 55. Suppose only 75% of all drivers in a certain state regularly wear a seat belt. A random sample of 500 drivers is selected. What is the probability that a. Between 360 and 400 (inclusive) of the drivers in the sample regularly wear a seat belt? b. Fewer than 400 of those in the sample regularly wear a seat belt? 56. Show that the relationship between a general normal percentile and the corresponding z percentile is as stated in this section. 57. a. Show that if X has a normal distribution with parameters m and s, then Y 5 aX 1 b (a linear function of X) also has a normal distribution. What are the parameters of the distribution of Y [i.e., E(Y ) and V(Y )]? [Hint: Write the cdf of Y, P(Y # y), as an integral involving the pdf of X, and then differentiate with respect to y to get the pdf of Y.] Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 165 4.4 The Exponential and Gamma Distributions b. If, when measured in 8C, temperature is normally distributed with mean 115 and standard deviation 2, what can be said about the distribution of temperature measured in 8F? 58. There is no nice formula for the standard normal cdf (z), but several good approximations have been published in articles. The following is from “Approximations for Hand Calculators Using Small Integer Coefficients” (Mathematics of Computation, 1977: 214–222). For 0 , z # 5.5, P(Z $ z) 5 1 2 (z) < .5 exp e 2c (83z 1 351)z 1 562 df 703/z 1 165 The relative error of this approximation is less than .042%. Use this to calculate approximations to the following probabilities, and compare whenever possible to the probabilities obtained from Appendix Table A.3. a. P(Z $ 1) b. P(Z , 23) c. P(24 , Z , 4) d. P(Z . 5) 4.4 The Exponential and Gamma Distributions The density curve corresponding to any normal distribution is bell-shaped and therefore symmetric. There are many practical situations in which the variable of interest to an investigator might have a skewed distribution. One family of distributions that has this property is the gamma family. We first consider a special case, the exponential distribution, and then generalize later in the section. The Exponential Distribution The family of exponential distributions provides probability models that are very widely used in engineering and science disciplines. DEFINITION X is said to have an exponential distribution with parameter l (l . 0) if the pdf of X is f (x; l) 5 e le2lx 0 x$0 otherwise (4.5) Some sources write the exponential pdf in the form (1/b)e2x/b, so that b 5 1/l. The expected value of an exponentially distributed random variable X is ` E(X) 5 3 xle2lx dx 0 Obtaining this expected value necessitates doing an integration by parts. The variance of X can be computed using the fact that V(X) 5 E(X 2) 2 [E(X)]2. The determination of E(X 2) requires integrating by parts twice in succession. The results of these integrations are as follows: m5 1 l s2 5 1 l2 Both the mean and standard deviation of the exponential distribution equal 1/l. Graphs of several exponential pdf’s are illustrated in Figure 4.26. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 166 CHAPTER 4 Continuous Random Variables and Probability Distributions f(x; ) 2 2 .5 1 1 .5 x Figure 4.26 Exponential density curves The exponential pdf is easily integrated to obtain the cdf. F(x; l) 5 e Example 4.21 0 x,0 1 2 e2lx x $ 0 The article “Probabilistic Fatigue Evaluation of Riveted Railway Bridges” (J. of Bridge Engr., 2008: 237–244) suggested the exponential distribution with mean value 6 MPa as a model for the distribution of stress range in certain bridge connections. Let’s assume that this is in fact the true model. Then E(X) 5 1/l 5 6 implies that l 5 .1667. The probability that stress range is at most 10 MPa is P(X # 10) 5 F(10 ; .1667) 5 1 2 e2(.1667)(10) 5 1 2 .189 5 .811 The probability that stress range is between 5 and 10 MPa is P(5 # X # 10) 5 F(10; .1667) 2 F(5; .1667) 5 (1 2 e21.667) 2 (1 2 e2.8335) 5 .246 ■ The exponential distribution is frequently used as a model for the distribution of times between the occurrence of successive events, such as customers arriving at a service facility or calls coming in to a switchboard. The reason for this is that the exponential distribution is closely related to the Poisson process discussed in Chapter 3. PROPOSITION Suppose that the number of events occurring in any time interval of length t has a Poisson distribution with parameter at (where a, the rate of the event process, is the expected number of events occurring in 1 unit of time) and that numbers of occurrences in nonoverlapping intervals are independent of one another. Then the distribution of elapsed time between the occurrence of two successive events is exponential with parameter l 5 a. Although a complete proof is beyond the scope of the text, the result is easily verified for the time X1 until the first event occurs: P(X1 # t) 5 1 2 P(X1 . t) 5 1 2 P[no events in (0, t)] e2at # (at)0 512 5 1 2 e2at 0! which is exactly the cdf of the exponential distribution. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.4 The Exponential and Gamma Distributions Example 4.22 167 Suppose that calls are received at a 24-hour “suicide hotline” according to a Poisson process with rate a 5 .5 call per day. Then the number of days X between successive calls has an exponential distribution with parameter value .5, so the probability that more than 2 days elapse between calls is P(X . 2) 5 1 2 P(X # 2) 5 1 2 F(2; .5) 5 e2(.5)(2) 5 .368 ■ The expected time between successive calls is 1/.5 5 2 days. Another important application of the exponential distribution is to model the distribution of component lifetime. A partial reason for the popularity of such applications is the “memoryless” property of the exponential distribution. Suppose component lifetime is exponentially distributed with parameter l. After putting the component into service, we leave for a period of t0 hours and then return to find the component still working; what now is the probability that it lasts at least an additional t hours? In symbols, we wish P(X $ t 1 t0 u X $ t0) . By the definition of conditional probability, P(X $ t 1 t0 uX $ t0) 5 P[(X $ t 1 t0) ¨ (X $ t0)] P(X $ t0) But the event X $ t0 in the numerator is redundant, since both events can occur if and only if X $ t 1 t0 . Therefore, P(X $ t 1 t0 uX $ t0) 5 P(X $ t 1 t0) 1 2 F(t 1 t0; l) 5 5 e2lt P(X $ t0) 1 2 F(t0; l) This conditional probability is identical to the original probability P(X $ t) that the component lasted t hours. Thus the distribution of additional lifetime is exactly the same as the original distribution of lifetime, so at each point in time the component shows no effect of wear. In other words, the distribution of remaining lifetime is independent of current age. Although the memoryless property can be justified at least approximately in many applied problems, in other situations components deteriorate with age or occasionally improve with age (at least up to a certain point). More general lifetime models are then furnished by the gamma, Weibull, and lognormal distributions (the latter two are discussed in the next section). The Gamma Function To define the family of gamma distributions, we first need to introduce a function that plays an important role in many branches of mathematics. DEFINITION For a . 0, the gamma function (a) is defined by ` (a) 5 3 x a21e2x dx (4.6) 0 The most important properties of the gamma function are the following: 1. For any a . 1, (a) 5 (a 2 1) # (a 2 1) [via integration by parts] 2. For any positive integer, n, (n) 5 (n 2 1)! 3. Q21R 5 1p Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 168 CHAPTER 4 Continuous Random Variables and Probability Distributions By Expression (4.6), if we let x a21e2x x$0 f(x; a) 5 • (a) 0 otherwise (4.7) ` then f(x; a) $ 0 and 3 f(x; a) dx 5 (a)/(a) 5 1, so f(x; a) satisfies the two 0 basic properties of a pdf. The Gamma Distribution DEFINITION A continuous random variable X is said to have a gamma distribution if the pdf of X is 1 x a21e2x/b a b (a) f(x; a, b) 5 • 0 x$0 (4.8) otherwise where the parameters a and b satisfy a . 0, b . 0. The standard gamma distribution has b 5 1, so the pdf of a standard gamma rv is given by (4.7). The exponential distribution results from taking a 5 1 and b 5 1/l. Figure 4.27(a) illustrates the graphs of the gamma pdf f(x; a, b) (4.8) for several (a, b) pairs, whereas Figure 4.27(b) presents graphs of the standard gamma pdf. For the standard pdf, when a # 1, f(x; a) is strictly decreasing as x increases from 0; when a . 1, f(x; a) rises from 0 at x 5 0 to a maximum and then decreases. The parameter b in (4.8) is called the scale parameter because values other than 1 either stretch or compress the pdf in the x direction. f (x; , ) 2, 1.0 f (x; ) 1 3 1 1.0 1, 0.5 1 2, .6 2 0.5 2, x 0 1 2 3 4 (a) Figure 4.27 5 6 2 1 7 5 x 0 1 2 3 4 5 (b) (a) Gamma density curves; (b) standard gamma density curves The mean and variance of a random variable X having the gamma distribution f(x; a, b) are E(X) 5 m 5 ab V(X) 5 s2 5 ab2 When X is a standard gamma rv, the cdf of X, x ya21e2y dy (a) 0 F(x; a) 5 3 x.0 (4.9) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.4 The Exponential and Gamma Distributions 169 is called the incomplete gamma function [sometimes the incomplete gamma function refers to Expression (4.9) without the denominator (a) in the integrand]. There are extensive tables of F(x; a) available; in Appendix Table A.4, we present a small tabulation for a 5 1, 2, c, 10 and x 5 1, 2, c,15. Example 4.23 Suppose the reaction time X of a randomly selected individual to a certain stimulus has a standard gamma distribution with a 5 2. Since P(a # X # b) 5 F(b) 2 F(a) when X is continuous, P(3 # X # 5) 5 F(5; 2) 2 F(3; 2) 5 .960 2 .801 5 .159 The probability that the reaction time is more than 4 sec is P(X . 4) 5 1 2 P(X # 4) 5 1 2 F(4; 2) 5 1 2 .908 5 .092 ■ The incomplete gamma function can also be used to compute probabilities involving nonstandard gamma distributions. These probabilities can also be obtained almost instantaneously from various software packages. PROPOSITION Let X have a gamma distribution with parameters a and b. Then for any x . 0, the cdf of X is given by P(X # x) 5 F(x; a, b) 5 Fa x ; ab b where F( # ; a)is the incomplete gamma function. Example 4.24 Suppose the survival time X in weeks of a randomly selected male mouse exposed to 240 rads of gamma radiation has a gamma distribution with a 5 8 and b 5 15. (Data in Survival Distributions: Reliability Applications in the Biomedical Services, by A. J. Gross and V. Clark, suggests a < 8.5 and b < 13.3.) The expected survival time is E(X) 5 (8)(15) 5 120 weeks, whereas V(X) 5 (8)(15)2 5 1800 and sX 5 11800 5 42.43 weeks. The probability that a mouse survives between 60 and 120 weeks is P(60 # X # 120) 5 P(X # 120) 2 P(X # 60) 5 F(120/15; 8) 2 F(60/15; 8) 5 F(8;8) 2 F(4;8) 5 .547 2 .051 5 .496 The probability that a mouse survives at least 30 weeks is P(X $ 30) 5 1 2 P(X , 30) 5 1 2 P(X # 30) 5 1 2 F(30/15; 8) 5 .999 ■ The Chi-Squared Distribution The chi-squared distribution is important because it is the basis for a number of procedures in statistical inference. The central role played by the chi-squared distribution in inference springs from its relationship to normal distributions (see Exercise 71). We’ll discuss this distribution in more detail in later chapters. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 170 CHAPTER 4 Continuous Random Variables and Probability Distributions DEFINITION Let n be a positive integer. Then a random variable X is said to have a chisquared distribution with parameter n if the pdf of X is the gamma density with a 5 n/2 and b 5 2. The pdf of a chi-squared rv is thus f(x; n) 5 u 1 x (n/2)21e2x/2 x $ 0 2n/2(v/2) 0 x,0 (4.10) The parameter n is called the number of degrees of freedom (df) of X. The symbol x 2 is often used in place of “chi-squared.” EXERCISES Section 4.4 (59–71) 59. Let X 5 the time between two successive arrivals at the drive-up window of a local bank. If X has an exponential distribution with l 5 1 (which is identical to a standard gamma distribution with a 5 1), compute the following: a. The expected time between two successive arrivals b. The standard deviation of the time between successive arrivals c. P(X # 4) d. P(2 # X # 5) 60. Let X denote the distance (m) that an animal moves from its birth site to the first territorial vacancy it encounters. Suppose that for banner-tailed kangaroo rats, X has an exponential distribution with parameter l 5 .01386 (as suggested in the article “Competition and Dispersal from Multiple Nests,” Ecology, 1997: 873–883). a. What is the probability that the distance is at most 100 m? At most 200 m? Between 100 and 200 m? b. What is the probability that distance exceeds the mean distance by more than 2 standard deviations? c. What is the value of the median distance? 61. Data collected at Toronto Pearson International Airport suggests that an exponential distribution with mean value 2.725 hours is a good model for rainfall duration (Urban Stormwater Management Planning with Analytical Probabilistic Models, 2000, p. 69). a. What is the probability that the duration of a particular rainfall event at this location is at least 2 hours? At most 3 hours? Between 2 and 3 hours? b. What is the probability that rainfall duration exceeds the mean value by more than 2 standard deviations? What is the probability that it is less than the mean value by more than one standard deviation? 62. The paper “Microwave Observations of Daily Antarctic Sea-Ice Edge Expansion and Contribution Rates” (IEEE Geosci. and Remote Sensing Letters, 2006: 54–58) states that “The distribution of the daily sea-ice advance/retreat from each sensor is similar and is approximately double exponential.” The proposed double exponential distribution has density function f(x) 5 .5le2l|x| for 2` , x , ` . The standard deviation is given as 40.9 km. a. What is the value of the parameter l? b. What is the probability that the extent of daily sea-ice change is within 1 standard deviation of the mean value? 63. A consumer is trying to decide between two long-distance calling plans. The first one charges a flat rate of 10¢ per minute, whereas the second charges a flat rate of 99¢ for calls up to 20 minutes in duration and then 10¢ for each additional minute exceeding 20 (assume that calls lasting a noninteger number of minutes are charged proportionately to a whole-minute’s charge). Suppose the consumer’s distribution of call duration is exponential with parameter l. a. Explain intuitively how the choice of calling plan should depend on what the expected call duration is. b. Which plan is better if expected call duration is 10 minutes? 15 minutes? [Hint: Let h1(x) denote the cost for the first plan when call duration is x minutes and let h2(x) be the cost function for the second plan. Give expressions for these two cost functions, and then determine the expected cost for each plan.] 64. Evaluate the following: a. (6) b. (5/2) c. F(4; 5) (the incomplete gamma function) d. F(5; 4) e. F(0 ; 4) 65. Let X have a standard gamma distribution with a 5 7. Evaluate the following: a. P(X # 5) b. P(X , 5) c. P(X . 8) d. P(3 # X # 8) e. P(3 , X , 8) f. P(X , 4 or X . 6) 66. Suppose the time spent by a randomly selected student who uses a terminal connected to a local time-sharing computer facility has a gamma distribution with mean 20 min and variance 80 min2. a. What are the values of a and b? b. What is the probability that a student uses the terminal for at most 24 min? c. What is the probability that a student spends between 20 and 40 min using the terminal? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.5 Other Continuous Distributions 67. Suppose that when a transistor of a certain type is subjected to an accelerated life test, the lifetime X (in weeks) has a gamma distribution with mean 24 weeks and standard deviation 12 weeks. a. What is the probability that a transistor will last between 12 and 24 weeks? b. What is the probability that a transistor will last at most 24 weeks? Is the median of the lifetime distribution less than 24? Why or why not? c. What is the 99th percentile of the lifetime distribution? d. Suppose the test will actually be terminated after t weeks. What value of t is such that only .5% of all transistors would still be operating at termination? 68. The special case of the gamma distribution in which a is a positive integer n is called an Erlang distribution. If we replace b by 1/l in Expression (4.8), the Erlang pdf is f(x; l, n) 5 • l(l x) n21e2lx x$0 (n 2 1)! 0 x,0 It can be shown that if the times between successive events are independent, each with an exponential distribution with parameter l, then the total time X that elapses before all of the next n events occur has pdf f(x; l, n). a. What is the expected value of X? If the time (in minutes) between arrivals of successive customers is exponentially distributed with l 5 .5, how much time can be expected to elapse before the tenth customer arrives? b. If customer interarrival time is exponentially distributed with l 5 .5, what is the probability that the tenth customer (after the one who has just arrived) will arrive within the next 30 min? c. The event {X # t} occurs iff at least n events occur in the next t units of time. Use the fact that the number of events occurring in an interval of length t has a Poisson distribution with parameter lt to write an expression 171 (involving Poisson probabilities) for the Erlang cdf F(t; l, n) 5 P(X # t). 69. A system consists of five identical components connected in series as shown: 1 2 3 4 5 As soon as one component fails, the entire system will fail. Suppose each component has a lifetime that is exponentially distributed with l 5 .01 and that components fail independently of one another. Define events Ai 5 {ith component lasts at least t hours}, i 5 1, c, 5, so that the Ais are independent events. Let X 5 the time at which the system fails—that is, the shortest (minimum) lifetime among the five components. a. The event {X $ t} is equivalent to what event involving A1, c, A5? b. Using the independence of the Airs, compute P(X $ t). Then obtain F(t) 5 P(X # t) and the pdf of X. What type of distribution does X have? c. Suppose there are n components, each having exponential lifetime with parameter l. What type of distribution does X have? 70. If X has an exponential distribution with parameter l, derive a general expression for the (100p)th percentile of the distribution. Then specialize to obtain the median. 71. a. The event {X 2 # y} is equivalent to what event involving X itself? b. If X has a standard normal distribution, use part (a) to write the integral that equals P(X 2 # y). Then differentiate this with respect to y to obtain the pdf of X 2 [the square of a N(0, 1) variable]. Finally, show that X 2 has a chi-squared distribution with n 5 1 df [see (4.10)]. [Hint: Use the following identity.] b(y) d e f(x) dx f 5 f [b(y)] # br(y) 2 f [a(y)] # a r(y) dy 3a(y) 4.5 Other Continuous Distributions The normal, gamma (including exponential), and uniform families of distributions provide a wide variety of probability models for continuous variables, but there are many practical situations in which no member of these families fits a set of observed data very well. Statisticians and other investigators have developed other families of distributions that are often appropriate in practice. The Weibull Distribution The family of Weibull distributions was introduced by the Swedish physicist Waloddi Weibull in 1939; his 1951 article “A Statistical Distribution Function of Wide Applicability” (J. of Applied Mechanics, vol. 18: 293–297) discusses a number of applications. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 172 CHAPTER 4 Continuous Random Variables and Probability Distributions DEFINITION A random variable X is said to have a Weibull distribution with parameters a and b (a . 0, b . 0) if the pdf of X is a a21 2(x/b)a x e x$0 f (x; a, b) 5 • ba 0 x,0 (4.11) In some situations, there are theoretical justifications for the appropriateness of the Weibull distribution, but in many applications f (x; a, b) simply provides a good fit to observed data for particular values of a and b. When a 5 1, the pdf reduces to the exponential distribution (with l 5 1/b), so the exponential distribution is a special case of both the gamma and Weibull distributions. However, there are gamma distributions that are not Weibull distributions and vice versa, so one family is not a subset of the other. Both a and b can be varied to obtain a number of different-looking density curves, as illustrated in Figure 4.28. b is called a scale parameter, since different values stretch or compress the graph in the x direction, and a is referred to as a shape parameter. f(x) 1 a = 1, b = 1 (exponential) a = 2, b = 1 .5 a = 2, b = .5 x 0 5 10 f(x) 8 6 a = 10, b = .5 4 a = 10, b = 1 a = 10, b = 2 2 x 0 0 .5 1.0 Figure 4.28 1.5 2.0 2.5 Weibull density curves Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.5 Other Continuous Distributions 173 Integrating to obtain E(X) and E(X 2) yields m 5 ba1 1 1 b a 2 1 2 s2 5 b2 e a1 1 b 2 ca1 1 b d f a a The computation of m and s2 thus necessitates using the gamma function. The integration 冕x0 f(y; a, b) dy is easily carried out to obtain the cdf of X. The cdf of a Weibull rv having parameters a and b is F(x; a, b) 5 e Example 4.25 0 x,0 2(x/b)a x$0 12e (4.12) In recent years the Weibull distribution has been used to model engine emissions of various pollutants. Let X denote the amount of NOx emission (g/gal) from a randomly selected four-stroke engine of a certain type, and suppose that X has a Weibull distribution with a 5 2 and b 5 10 (suggested by information in the article “Quantification of Variability and Uncertainty in Lawn and Garden Equipment NOx and Total Hydrocarbon Emission Factors,” J. of the Air and Waste Management Assoc., 2002: 435–448). The corresponding density curve looks exactly like the one in Figure 4.28 for a 5 2, b 5 1 except that now the values 50 and 100 replace 5 and 10 on the horizontal axis (because b is a “scale parameter”). Then 2 P(X # 10) 5 F(10; 2, 10) 5 1 2 e2(10/10) 5 1 2 e21 5 .632 Similarly, P(X # 25) 5 .998, so the distribution is almost entirely concentrated on values between 0 and 25. The value c which separates the 5% of all engines having the largest amounts of NOx emissions from the remaining 95% satisfies 2 .95 5 1 2 e2(c/10) Isolating the exponential term on one side, taking logarithms, and solving the resulting equation gives c < 17.3 as the 95th percentile of the emission distribution. ■ In practical situations, a Weibull model may be reasonable except that the smallest possible X value may be some value g not assumed to be zero (this would also apply to a gamma model). The quantity g can then be regarded as a third (threshold) parameter of the distribution, which is what Weibull did in his original work. For, say, g 5 3, all curves in Figure 4.28 would be shifted 3 units to the right. This is equivalent to saying that X 2 g has the pdf (4.11), so that the cdf of X is obtained by replacing x in (4.12) by x 2 g. Example 4.26 An understanding of the volumetric properties of asphalt is important in designing mixtures which will result in high-durability pavement. The article “Is a Normal Distribution the Most Appropriate Statistical Distribution for Volumetric Properties in Asphalt Mixtures?” (J. of Testing and Evaluation, Sept. 2009: 1–11) used the analysis of some sample data to recommend that for a particular mixture, X = air void volume (%) be modeled with a three-parameter Weibull distribution. Suppose the values of the parameters are g = 4, a = 1.3, and b = .8 (quite close to estimates given in the article). For x . 4, the cumulative distribution function is 1.3 F(x; a, b, g) 5 F(x; 1.3, .8, 4) 5 1 2 e2[(x24)/.8] Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 174 CHAPTER 4 Continuous Random Variables and Probability Distributions The probability that the air void volume of a specimen is between 5% and 6% is 1.3 1.3 P(5 # X # 6) 5 F(6; 1.3,.8,4) 2 F(5; 1.3, .8, 4) 5 e2[(524)/.8] 2 e2[(624)/.8] 5 .263 2 .037 5 .226 Figure 4.29 shows a graph from Minitab of the corresponding Weibull density function in which the shaded area corresponds to the probability just calculated. f(x) 0.9 0.8 Density 0.7 0.6 0.5 0.4 0.3 0.226 0.2 0.1 x 0.0 4 Figure 4.29 5 6 Weibull density curve with threshold = 4, shape = 1.3, scale = .8 ■ The Lognormal Distribution DEFINITION A nonnegative rv X is said to have a lognormal distribution if the rv Y 5 ln(X) has a normal distribution. The resulting pdf of a lognormal rv when ln(X) is normally distributed with parameters m and s is 1 f (x; m, s) 5 u 12psx 2 2 e2[ln(x)2m] /(2s ) x$0 0 x,0 Be careful here; the parameters m and s are not the mean and standard deviation of X but of ln(X ). It is common to refer to m and s as the location and the scale parameters, respectively. The mean and variance of X can be shown to be 2 E(X) 5 em1s /2 2 V(X) 5 e2m1s # (e s 2 2 1) In Chapter 5, we will present a theoretical justification for this distribution in connection with the Central Limit Theorem, but as with other distributions, the lognormal can be used as a model even in the absence of such justification. Figure 4.30 illustrates graphs of the lognormal pdf; although a normal curve is symmetric, a lognormal curve has a positive skew. Because ln(X) has a normal distribution, the cdf of X can be expressed in terms of the cdf (z) of a standard normal rv Z. F(x; m, s) 5 P(X # x) 5 P[ln(X) # ln(x)] ln(x) 2 m ln(x) 2 m 5 PaZ # b 5 a b s s x$0 (4.13) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 175 4.5 Other Continuous Distributions f(x) .25 .20 μ = 1, σ = 1 .15 μ = 3, σ = √3 .10 μ = 3, σ = 1 .05 x 0 0 5 10 Figure 4.30 Example 4.27 15 20 25 Lognormal density curves According to the article “Predictive Model for Pitting Corrosion in Buried Oil and Gas Pipelines” (Corrosion, 2009: 332–342), the lognormal distribution has been reported as the best option for describing the distribution of maximum pit depth data from cast iron pipes in soil. The authors suggest that a lognormal distribution with m = .353 and s = .754 is appropriate for maximum pit depth (mm) of buried pipelines. For this distribution, the mean value and variance of pit depth are 2 E(X) 5 e.3531(.754) /2 5 e.6373 5 1.891 2 V(X) 5 e2(.353)1(.754) # (e(.754) 2 2 1) 5 (3.57697)(.765645) 5 2.7387 The probability that maximum pit depth is between 1 and 2 mm is P(1 # X # 2) 5 P(ln(1) # ln(X) # ln(2)) 5 P(0 # ln(X) # .693) 0 2 .353 .693 2 .353 5 Pa #Z# b 5 (.47) 2 (2.45) 5 .354 .754 .754 This probability is illustrated in Figure 4.31 (from Minitab). f(x) 0.5 0.4 Density 0.354 0.3 0.2 0.1 x 0.0 0 Figure 4.31 1 2 Lognormal density curve with location = .353 and scale = .754 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 176 CHAPTER 4 Continuous Random Variables and Probability Distributions What value c is such that only 1% of all specimens have a maximum pit depth exceeding c? The desired value satisfies .99 5 P(X # c) 5 PaZ # ln(c) 2 .353 b .754 The z critical value 2.33 captures an upper-tail area of .01 (z.01 = 2.33), and thus a cumulative area of .99. This implies that ln(c) 2 .353 5 2.33 .754 from which ln(c) = 2.1098 and c = 8.247. Thus 8.247 is the 99th percentile of the maximum pit depth distribution. ■ The Beta Distribution All families of continuous distributions discussed so far except for the uniform distribution have positive density over an infinite interval (though typically the density function decreases rapidly to zero beyond a few standard deviations from the mean). The beta distribution provides positive density only for X in an interval of finite length. DEFINITION A random variable X is said to have a beta distribution with parameters a, b (both positive), A, and B if the pdf of X is 1 # (a 1 b) x 2 A a21 B 2 x b21 a b a b A#x#B f(x; a, b, A, B) 5 • B 2 A (a) # (b) B 2 A B2A 0 otherwise The case A 5 0, B 5 1 gives the standard beta distribution. Figure 4.32 illustrates several standard beta pdf’s. Graphs of the general pdf are similar, except they are shifted and then stretched or compressed to fit over [A, B]. Unless a and b are integers, integration of the pdf to calculate probabilities is difficult. Either a table of the incomplete beta function or appropriate software should be used. The mean and variance of X are m 5 A 1 (B 2 A) # a a1b s2 5 (B 2 A)2ab (a 1 b)2(a 1 b 1 1) f(x; , ) 5 2 .5 4 5 2 3 2 .5 1 x 0 .2 Figure 4.32 .4 .6 .8 1 Standard beta density curves Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.5 Other Continuous Distributions Example 4.28 177 Project managers often use a method labeled PERT—for program evaluation and review technique—to coordinate the various activities making up a large project. (One successful application was in the construction of the Apollo spacecraft.) A standard assumption in PERT analysis is that the time necessary to complete any particular activity once it has been started has a beta distribution with A 5 the optimistic time (if everything goes well) and B 5 the pessimistic time (if everything goes badly). Suppose that in constructing a single-family house, the time X (in days) necessary for laying the foundation has a beta distribution with A 5 2, B 5 5, a 5 2, and b 5 3. Then a/(a 1 b) 5 .4, so E(X) 5 2 1 (3)(.4) 5 3.2. For these values of a and b, the pdf of X is a simple polynomial function. The probability that it takes at most 3 days to lay the foundation is 3 52x 2 1 4! x 2 2 a ba b dx P(X # 3) 5 3 # 3 1!2! 3 3 2 4 3 4 # 11 11 5 3 (x 2 2)(5 2 x)2dx 5 5 5 .407 27 2 27 4 27 ■ The standard beta distribution is commonly used to model variation in the proportion or percentage of a quantity occurring in different samples, such as the proportion of a 24-hour day that an individual is asleep or the proportion of a certain element in a chemical compound. EXERCISES Section 4.5 (72–86) 72. The lifetime X (in hundreds of hours) of a certain type of vacuum tube has a Weibull distribution with parameters a 5 2 and b 5 3. Compute the following: a. E(X) and V(X) b. P(X # 6) c. P(1.5 # X # 6) (This Weibull distribution is suggested as a model for time in service in “On the Assessment of Equipment Reliability: Trading Data Collection Costs for Precision,” J. of Engr. Manuf., 1991: 105–109.) 73. The authors of the article “A Probabilistic Insulation Life Model for Combined Thermal-Electrical Stresses” (IEEE Trans. on Elect. Insulation, 1985: 519–522) state that “the Weibull distribution is widely used in statistical problems relating to aging of solid insulating materials subjected to aging and stress.” They propose the use of the distribution as a model for time (in hours) to failure of solid insulating specimens subjected to AC voltage. The values of the parameters depend on the voltage and temperature; suppose a 5 2.5 and b 5 200 (values suggested by data in the article). a. What is the probability that a specimen’s lifetime is at most 250? Less than 250? More than 300? b. What is the probability that a specimen’s lifetime is between 100 and 250? c. What value is such that exactly 50% of all specimens have lifetimes exceeding that value? 74. Let X 5 the time (in 1021 weeks) from shipment of a defective product until the customer returns the product. Suppose that the minimum return time is g 5 3.5 and that the excess X 2 3.5 over the minimum has a Weibull distribution with parameters a 5 2 and b 5 1.5 (see “Practical Applications of the Weibull Distribution,” Industrial Quality Control, Aug. 1964: 71–78). a. What is the cdf of X? b. What are the expected return time and variance of return time? [Hint: First obtain E(X 2 3.5) and V(X 2 3.5).] c. Compute P(X . 5). d. Compute P(5 # X # 8). 75. Let X have a Weibull distribution with the pdf from Expression (4.11). Verify that m 5 b(1 1 1/a). [Hint: In the integral for E(X), make the change of variable y 5 (x/b)a, so that x 5 by1/a.] 76. a. In Exercise 72, what is the median lifetime of such tubes? [Hint: Use Expression (4.12).] b. In Exercise 74, what is the median return time? c. If X has a Weibull distribution with the cdf from Expression (4.12), obtain a general expression for the (100p)th percentile of the distribution. d. In Exercise 74, the company wants to refuse to accept returns after t weeks. For what value of t will only 10% of all returns be refused? 77. The authors of the paper from which the data in Exercise 1.27 was extracted suggested that a reasonable probability model for drill lifetime was a lognormal distribution with m 5 4.5 and s 5 .8. a. What are the mean value and standard deviation of lifetime? b. What is the probability that lifetime is at most 100? c. What is the probability that lifetime is at least 200? Greater than 200? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 178 CHAPTER 4 Continuous Random Variables and Probability Distributions 78. The article “On Assessing the Accuracy of Offshore Wind Turbine Reliability-Based Design Loads from the Environmental Contour Method” (Intl. J. of Offshore and Polar Engr., 2005: 132–140) proposes the Weibull distribution with a 5 1.817 and b 5 .863 as a model for 1-hour significant wave height (m) at a certain site. a. What is the probability that wave height is at most .5 m? b. What is the probability that wave height exceeds its mean value by more than one standard deviation? c. What is the median of the wave-height distribution? d. For 0 , p , 1, give a general expression for the 100pth percentile of the wave-height distribution. 79. Nonpoint source loads are chemical masses that travel to the main stem of a river and its tributaries in flows that are distributed over relatively long stream reaches, in contrast to those that enter at well-defined and regulated points. The article “Assessing Uncertainty in Mass Balance Calculation of River Nonpoint Source Loads” (J. of Envir. Engr., 2008: 247–258) suggested that for a certain time period and location, X 5 nonpoint source load of total dissolved solids could be modeled with a lognormal distribution having mean value 10,281 kg/day/km and a coefficient of variation CV 5 .40 (CV 5 sX/mX). a. What are the mean value and standard deviation of ln(X)? b. What is the probability that X is at most 15,000 kg/day/km? c. What is the probability that X exceeds its mean value, and why is this probability not .5? d. Is 17,000 the 95th percentile of the distribution? | 80. a. Use Equation (4.13) to write a formula for the median m of the lognormal distribution. What is the median for the load distribution of Exercise 79? b. Recalling that za is our notation for the 100(1 2 a) percentile of the standard normal distribution, write an expression for the 100(1 2 a) percentile of the lognormal distribution. In Exercise 79, what value will load exceed only 1% of the time? 81. A theoretical justification based on a certain material failure mechanism underlies the assumption that ductile strength X of a material has a lognormal distribution. Suppose the parameters are m 5 5 and s 5 .1. a. Compute E(X) and V(X). b. c. d. e. Compute P(X . 125). Compute P(110 # X # 125). What is the value of median ductile strength? If ten different samples of an alloy steel of this type were subjected to a strength test, how many would you expect to have strength of at least 125? f. If the smallest 5% of strength values were unacceptable, what would the minimum acceptable strength be? 82. The article “The Statistics of Phytotoxic Air Pollutants” (J. of Royal Stat. Soc., 1989: 183–198) suggests the lognormal distribution as a model for SO2 concentration above a certain forest. Suppose the parameter values are m 5 1.9 and s 5 .9. a. What are the mean value and standard deviation of concentration? b. What is the probability that concentration is at most 10? Between 5 and 10? 83. What condition on a and b is necessary for the standard beta pdf to be symmetric? 84. Suppose the proportion X of surface area in a randomly selected quadrat that is covered by a certain plant has a standard beta distribution with a 5 5 and b 5 2. a. Compute E(X) and V(X). b. Compute P(X # .2). c. Compute P(.2 # X # .4). d. What is the expected proportion of the sampling region not covered by the plant? 85. Let X have a standard beta density with parameters a and b. a. Verify the formula for E(X) given in the section. b. Compute E[(1 2 X)m]. If X represents the proportion of a substance consisting of a particular ingredient, what is the expected proportion that does not consist of this ingredient? 86. Stress is applied to a 20-in. steel bar that is clamped in a fixed position at each end. Let Y 5 the distance from the left end at which the bar snaps. Suppose Y/20 has a standard beta distribution with E(Y) 5 10 and V(Y) 5 100. 7 a. What are the parameters of the relevant standard beta distribution? b. Compute P(8 # Y # 12). c. Compute the probability that the bar snaps more than 2 in. from where you expect it to. 4.6 Probability Plots An investigator will often have obtained a numerical sample x1, x2, c, xn and wish to know whether it is plausible that it came from a population distribution of some particular type (e.g., from a normal distribution). For one thing, many formal procedures from statistical inference are based on the assumption that the population distribution is of a specified type. The use of such a procedure is inappropriate if the actual underlying probability distribution differs greatly from the assumed type. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.6 Probability Plots 179 For example, the article “Toothpaste Detergents: A Potential Source of Oral Soft Tissue Damage” (Intl. J. of Dental Hygiene, 2008: 193–198) contains the following statement: “Because the sample number for each experiment (replication) was limited to three wells per treatment type, the data were assumed to be normally distributed.” As justification for this leap of faith, the authors wrote that “Descriptive statistics showed standard deviations that suggested a normal distribution to be highly likely.” Note: This argument is not very persuasive. Additionally, understanding the underlying distribution can sometimes give insight into the physical mechanisms involved in generating the data. An effective way to check a distributional assumption is to construct what is called a probability plot. The essence of such a plot is that if the distribution on which the plot is based is correct, the points in the plot should fall close to a straight line. If the actual distribution is quite different from the one used to construct the plot, the points will likely depart substantially from a linear pattern. Sample Percentiles The details involved in constructing probability plots differ a bit from source to source. The basis for our construction is a comparison between percentiles of the sample data and the corresponding percentiles of the distribution under consideration. Recall that the (100p)th percentile of a continuous distribution with cdf F( # )is the number h(p) that satisfies F(h(p)) 5 p. That is, h(p) is the number on the measurement scale such that the area under the density curve to the left of h(p) is p. Thus the 50th percentile h(.5) satisfies F(h(.5)) 5 .5, and the 90th percentile satisfies F(h(.9)) 5 .9. Consider as an example the standard normal distribution, for which we have denoted the cdf by ( # ). From Appendix Table A.3, we find the 20th percentile by locating the row and column in which .2000 (or a number as close to it as possible) appears inside the table. Since .2005 appears at the intersection of the 2.8 row and the .04 column, the 20th percentile is approximately 2.84. Similarly, the 25th percentile of the standard normal distribution is (using linear interpolation) approximately 2.675. Roughly speaking, sample percentiles are defined in the same way that percentiles of a population distribution are defined. The 50th-sample percentile should separate the smallest 50% of the sample from the largest 50%, the 90th percentile should be such that 90% of the sample lies below that value and 10% lies above, and so on. Unfortunately, we run into problems when we actually try to compute the sample percentiles for a particular sample of n observations. If, for example, n 5 10, we can split off 20% of these values or 30% of the data, but there is no value that will split off exactly 23% of these ten observations. To proceed further, we need an operational definition of sample percentiles (this is one place where different people do slightly different things). Recall that when n is odd, the sample median or 50thsample percentile is the middle value in the ordered list, for example, the sixth-largest value when n 5 11. This amounts to regarding the middle observation as being half in the lower half of the data and half in the upper half. Similarly, suppose n 5 10. Then if we call the third-smallest value the 25th percentile, we are regarding that value as being half in the lower group (consisting of the two smallest observations) and half in the upper group (the seven largest observations). This leads to the following general definition of sample percentiles. DEFINITION Order the n sample observations from smallest to largest. Then the ith smallest observation in the list is taken to be the [100(i 2 .5)/n]th sample percentile. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 180 CHAPTER 4 Continuous Random Variables and Probability Distributions Once the percentage values 100(i 2 .5)/n (i 5 1, 2, c, n) have been calculated, sample percentiles corresponding to intermediate percentages can be obtained by linear interpolation. For example, if n 5 10, the percentages corresponding to the ordered sample observations are 100(1 2 .5)/10 5 5%, 100(2 2 .5)/10 5 15%, 25%, c, and 100(10 2 .5)/10 5 95%. The 10th percentile is then halfway between the 5th percentile (smallest sample observation) and the 15th percentile (second-smallest observation). For our purposes, such interpolation is not necessary because a probability plot will be based only on the percentages 100(i 2 .5)/n corresponding to the n sample observations. A Probability Plot Suppose now that for percentages 100(i 2 .5)/n (i 5 1, c, n) the percentiles are determined for a specified population distribution whose plausibility is being investigated. If the sample was actually selected from the specified distribution, the sample percentiles (ordered sample observations) should be reasonably close to the corresponding population distribution percentiles. That is, for i 5 1, 2, c, n there should be reasonable agreement between the ith smallest sample observation and the [100(i 2 .5)/n]th percentile for the specified distribution. Let’s consider the (population percentile, sample percentile) pairs—that is, the pairs a [100(i 2 .5)/n]th percentile , of the distribution, ith smallest sample b observation for i 5 1, c, n. Each such pair can be plotted as a point on a two-dimensional coordinate system. If the sample percentiles are close to the corresponding population distribution percentiles, the first number in each pair will be roughly equal to the second number. The plotted points will then fall close to a 458 line. Substantial deviations of the plotted points from a 458 line cast doubt on the assumption that the distribution under consideration is the correct one. Example 4.29 The value of a certain physical constant is known to an experimenter. The experimenter makes n 5 10 independent measurements of this value using a particular measurement device and records the resulting measurement errors (error 5 observed value 2 true value). These observations appear in the accompanying table. Percentage 5 15 25 35 45 z percentile 21.645 21.037 2.675 2.385 2.126 21.91 21.25 2.75 2.53 .20 Percentage 55 65 75 85 95 z percentile .126 .385 .675 1.037 1.645 .35 .72 .87 1.40 1.56 Sample observation Sample observation Is it plausible that the random variable measurement error has a standard normal distribution? The needed standard normal (z) percentiles are also displayed in the table. Thus the points in the probability plot are (21.645, 21.91), (21.037, 21.25), c, and (1.645, 1.56). Figure 4.33 shows the resulting plot. Although the points deviate a bit from the 458 line, the predominant impression is that this line fits the points Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.6 Probability Plots 181 very well. The plot suggests that the standard normal distribution is a reasonable probability model for measurement error. x 45° line 1.6 1.2 .8 .4 z percentile 1.6 1.2 .8 .4 .4 .4 .8 1.2 1.6 .8 1.2 1.6 1.8 Figure 4.33 first sample Plots of pairs (z percentile, observed value) for the data of Example 4.29: Figure 4.34 shows a plot of pairs (z percentile, observation) for a second sample of ten observations. The 458 line gives a good fit to the middle part of the sample but not to the extremes. The plot has a well-defined S-shaped appearance. The two smallest sample observations are considerably larger than the corresponding z percentiles (the points on the far left of the plot are well above the 458 line). Similarly, the two largest sample observations are much smaller than the associated z percentiles. This plot indicates that the standard normal distribution would not be a plausible choice for the probability model that gave rise to these observed measurement errors. 45° line x 1.2 S-shaped curve .8 .4 z percentile 1.6 1.2 .8 .4 .4 .4 .8 1.2 1.6 .8 1.2 Figure 4.34 Plots of pairs (z percentile, observed value) for the data of Example 4.29: second sample ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 182 CHAPTER 4 Continuous Random Variables and Probability Distributions An investigator is typically not interested in knowing just whether a specified probability distribution, such as the standard normal distribution (normal with m 5 0 and s 5 1) or the exponential distribution with l 5 .1, is a plausible model for the population distribution from which the sample was selected. Instead, the issue is whether some member of a family of probability distributions specifies a plausible model—the family of normal distributions, the family of exponential distributions, the family of Weibull distributions, and so on. The values of the parameters of a distribution are usually not specified at the outset. If the family of Weibull distributions is under consideration as a model for lifetime data, are there any values of the parameters a and b for which the corresponding Weibull distribution gives a good fit to the data? Fortunately, it is almost always the case that just one probability plot will suffice for assessing the plausibility of an entire family. If the plot deviates substantially from a straight line, no member of the family is plausible. When the plot is quite straight, further work is necessary to estimate values of the parameters that yield the most reasonable distribution of the specified type. Let’s focus on a plot for checking normality. Such a plot is useful in applied work because many formal statistical procedures give accurate inferences only when the population distribution is at least approximately normal. These procedures should generally not be used if the normal probability plot shows a very pronounced departure from linearity. The key to constructing an omnibus normal probability plot is the relationship between standard normal (z) percentiles and those for any other normal distribution: percentile for a normal (m, s) distribution 5 m 1 s # (corresponding z percentile) Consider first the case m 5 0. If each observation is exactly equal to the corresponding normal percentile for some value of s, the pairs (s # [z percentile], observation) fall on a 458 line, which has slope 1. This then implies that the (z percentile, observation) pairs fall on a line passing through (0, 0) (i.e., one with y-intercept 0) but having slope s rather than 1. The effect of a nonzero value of m is simply to change the y-intercept from 0 to m. A plot of the n pairs ([100(i 2 .5)/n]th z percentile, ith smallest observation) on a two-dimensional coordinate system is called a normal probability plot. If the sample observations are in fact drawn from a normal distribution with mean value m and standard deviation s, the points should fall close to a straight line with slope s and intercept m. Thus a plot for which the points fall close to some straight line suggests that the assumption of a normal population distribution is plausible. Example 4.30 The accompanying sample consisting of n 5 20 observations on dielectric breakdown voltage of a piece of epoxy resin appeared in the article “Maximum Likelihood Estimation in the 3-Parameter Weibull Distribution (IEEE Trans. on Dielectrics and Elec. Insul., 1996: 43–55). The values of (i 2 .5)/n for which z percentiles are needed are (1 2 .5)/20 5 .025, (2 2 .5)/20 5 .075, c, and .975. Observation 24.46 25.61 26.25 26.42 26.66 27.15 27.31 27.54 27.74 27.94 z percentile 21.96 21.44 21.15 2.93 2.76 2.60 2.45 2.32 2.19 2.06 Observation z percentile 27.98 .06 28.04 .19 28.28 28.49 28.50 28.87 29.11 29.13 29.50 30.88 .32 .45 .60 .76 .93 1.15 1.44 1.96 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.6 Probability Plots 183 Figure 4.35 shows the resulting normal probability plot. The pattern in the plot is quite straight, indicating it is plausible that the population distribution of dielectric breakdown voltage is normal. x 31 30 29 28 27 26 25 24 z percentile –2 Figure 4.35 –1 0 1 2 Normal probability plot for the dielectric breakdown voltage sample ■ There is an alternative version of a normal probability plot in which the z percentile axis is replaced by a nonlinear probability axis. The scaling on this axis is constructed so that plotted points should again fall close to a line when the sampled distribution is normal. Figure 4.36 shows such a plot from Minitab for the breakdown voltage data of Example 4.30. .999 .99 Probability .95 .80 .50 .20 .05 .01 .001 24.2 Figure 4.36 25.2 26.2 28.2 27.2 Voltage 29.2 30.2 31.2 Normal probability plot of the breakdown voltage data from Minitab A nonnormal population distribution can often be placed in one of the following three categories: 1. It is symmetric and has “lighter tails” than does a normal distribution; that is, the density curve declines more rapidly out in the tails than does a normal curve. 2. It is symmetric and heavy-tailed compared to a normal distribution. 3. It is skewed. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 184 CHAPTER 4 Continuous Random Variables and Probability Distributions A uniform distribution is light-tailed, since its density function drops to zero outside a finite interval. The density function f (x) 5 1/[p(1 1 x 2)] for 2` , x , ` is 2 heavy-tailed, since 1/(1 1 x 2) declines much less rapidly than does e2x /2. Lognormal and Weibull distributions are among those that are skewed. When the points in a normal probability plot do not adhere to a straight line, the pattern will frequently suggest that the population distribution is in a particular one of these three categories. When the distribution from which the sample is selected is light-tailed, the largest and smallest observations are usually not as extreme as would be expected from a normal random sample. Visualize a straight line drawn through the middle part of the plot; points on the far right tend to be below the line (observed value , z percentile), whereas points on the left end of the plot tend to fall above the straight line (observed value . z percentile). The result is an S-shaped pattern of the type pictured in Figure 4.34. A sample from a heavy-tailed distribution also tends to produce an S-shaped plot. However, in contrast to the light-tailed case, the left end of the plot curves downward (observed , z percentile), as shown in Figure 4.37(a). If the underlying distribution is positively skewed (a short left tail and a long right tail), the smallest sample observations will be larger than expected from a normal sample and so will the largest observations. In this case, points on both ends of the plot will fall above a straight line through the middle part, yielding a curved pattern, as illustrated in Figure 4.37(b). A sample from a lognormal distribution will usually produce such a pattern. A plot of (z percentile, ln(x)) pairs should then resemble a straight line. x x z percentile z percentile (a) (b) Figure 4.37 Probability plots that suggest a nonnormal distribution: (a) a plot consistent with a heavy-tailed distribution; (b) a plot consistent with a positively skewed distribution Even when the population distribution is normal, the sample percentiles will not coincide exactly with the theoretical percentiles because of sampling variability. How much can the points in the probability plot deviate from a straight-line pattern before the assumption of population normality is no longer plausible? This is not an easy question to answer. Generally speaking, a small sample from a normal distribution is more likely to yield a plot with a nonlinear pattern than is a large sample. The book Fitting Equations to Data (see the Chapter 13 bibliography) presents the results of a simulation study in which numerous samples of different sizes were selected from normal distributions. The authors concluded that there is typically Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.6 Probability Plots 185 greater variation in the appearance of the probability plot for sample sizes smaller than 30, and only for much larger sample sizes does a linear pattern generally predominate. When a plot is based on a small sample size, only a very substantial departure from linearity should be taken as conclusive evidence of nonnormality. A similar comment applies to probability plots for checking the plausibility of other types of distributions. Beyond Normality Consider a family of probability distributions involving two parameters, u1 and u2, and let F(x; u1, u2) denote the corresponding cdf’s. The family of normal distributions is one such family, with u1 5 m, u2 5 s, and F(x; m, s) 5 [(x 2 m)/s]. Another example is the Weibull family, with u1 5 a, u2 5 b, and a F(x; a, b) 5 1 2 e2(x/b) Still another family of this type is the gamma family, for which the cdf is an integral involving the incomplete gamma function that cannot be expressed in any simpler form. The parameters u1 and u2 are said to be location and scale parameters, respectively, if F(x; u1, u2) is a function of (x 2 u1)/u2. The parameters m and s of the normal family are location and scale parameters, respectively. Changing m shifts the location of the bell-shaped density curve to the right or left, and changing s amounts to stretching or compressing the measurement scale (the scale on the horizontal axis when the density function is graphed). Another example is given by the cdf (x2u1)/u2 F(x; u1, u2) 5 1 2 e2e 2` , x , ` A random variable with this cdf is said to have an extreme value distribution. It is used in applications involving component lifetime and material strength. Although the form of the extreme value cdf might at first glance suggest that u1 is the point of symmetry for the density function, and therefore the mean and median, this is not the case. Instead, P(X # u1) 5 F(u1; u1, u2) 5 1 2 e21 5 .632, and the density function f(x; u1, u2) 5 Fr(x; u1, u2) is negatively skewed (a long lower tail). Similarly, the scale parameter u2 is not the standard deviation (m 5 u1 2 .5772u2 and s 5 1.283u2). However, changing the value of u1 does change the location of the density curve, whereas a change in u2 rescales the measurement axis. The parameter b of the Weibull distribution is a scale parameter, but a is not a location parameter. A similar comment applies to the parameters a and b of the gamma distribution. In the usual form, the density function for any member of either the gamma or Weibull distribution is positive for x . 0 and zero otherwise. A location parameter can be introduced as a third parameter g (we did this for the Weibull distribution) to shift the density function so that it is positive if x . g and zero otherwise. When the family under consideration has only location and scale parameters, the issue of whether any member of the family is a plausible population distribution can be addressed via a single, easily constructed probability plot. One first obtains the percentiles of the standard distribution, the one with u1 5 0 and u2 5 1, for percentages 100(i 2 .5)/n (i 5 1, c, n). The n (standardized percentile, observation) pairs give the points in the plot. This is exactly what we did to obtain an omnibus normal probability plot. Somewhat surprisingly, this methodology can be applied to yield an omnibus Weibull probability plot. The key result is that if X has a Weibull distribution with shape parameter a and scale parameter b, then the transformed Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 186 CHAPTER 4 Continuous Random Variables and Probability Distributions variable ln(X) has an extreme value distribution with location parameter u1 5 ln(b) and scale parameter 1/a. Thus a plot of the (extreme value standardized percentile, ln(x)) pairs showing a strong linear pattern provides support for choosing the Weibull distribution as a population model. Example 4.31 The accompanying observations are on lifetime (in hours) of power apparatus insulation when thermal and electrical stress acceleration were fixed at particular values (“On the Estimation of Life of Power Apparatus Insulation Under Combined Electrical and Thermal Stress,” IEEE Trans. on Electrical Insulation, 1985: 70–78). A Weibull probability plot necessitates first computing the 5th, 15th, . . . , and 95th percentiles of the standard extreme value distribution. The (100p)th percentile h(p) satisfies h(p) p 5 F(h(p)) 5 1 2 e2e from which h( p) 5 ln[2ln(1 2 p)]. Percentile 22.97 21.82 21.25 2.84 2.51 x 282 501 741 851 1072 ln(x) 5.64 6.22 6.61 6.75 6.98 Percentile 2.23 .05 .33 .64 1.10 x 1122 1202 1585 1905 2138 ln(x) 7.02 7.09 7.37 7.55 7.67 The pairs (22.97, 5.64), (21.82, 6.22), c, (1.10, 7.67) are plotted as points in Figure 4.38. The straightness of the plot argues strongly for using the Weibull distribution as a model for insulation life, a conclusion also reached by the author of the cited article. ln(x) 8 7 6 5 Percentile 3 Figure 4.38 2 1 0 1 A Weibull probability plot of the insulation lifetime data ■ The gamma distribution is an example of a family involving a shape parameter for which there is no transformation h( # ) such that h(X) has a distribution that depends only on location and scale parameters. Construction of a probability plot necessitates first estimating the shape parameter from sample data (some methods for doing this are described in Chapter 6). Sometimes an investigator wishes to know Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 4.6 Probability Plots 187 whether the transformed variable X u has a normal distribution for some value of u (by convention, u 5 0 is identified with the logarithmic transformation, in which case X has a lognormal distribution). The book Graphical Methods for Data Analysis, listed in the Chapter 1 bibliography, discusses this type of problem as well as other refinements of probability plotting. Fortunately, the wide availability of various probability plots with statistical software packages means that the user can often sidestep technical details. EXERCISES Section 4.6 (87–97) 87. The accompanying normal probability plot was constructed from a sample of 30 readings on tension for mesh screens behind the surface of video display tubes used in computer monitors. Does it appear plausible that the tension distribution is normal? 22–26). Would you feel comfortable estimating population mean thickness using a method that assumed a normal population distribution? .83 1.48 .88 1.49 .88 1.59 1.04 1.62 1.09 1.65 1.12 1.71 1.29 1.76 1.31 1.83 x 90. The article “A Probabilistic Model of Fracture in Concrete and Size Effects on Fracture Toughness” (Magazine of Concrete Res., 1996: 311–320) gives arguments for why fracture toughness in concrete specimens should have a Weibull distribution and presents several histograms of data that appear well fit by superimposed Weibull curves. Consider the following sample of size n 5 18 observations on toughness for high-strength concrete (consistent with one of the histograms); values of pi 5 (i 2 .5)/18 are also given. 350 300 250 200 z percentile –2 –1 0 1 2 88. A sample of 15 female collegiate golfers was selected and the clubhead velocity (km/hr) while swinging a driver was determined for each one, resulting in the following data (“Hip Rotational Velocities During the Full Golf Swing,” J. of Sports Science and Medicine, 2009: 296–299): 69.0 85.0 89.3 69.7 86.0 90.7 72.7 86.3 91.0 80.3 86.7 92.5 81.0 87.7 93.0 The corresponding z percentiles are 21.83 0.34 0.52 1.28 0.17 0.73 0.97 0.0 0.97 0.73 0.17 1.28 0.52 0.34 1.83 Construct a normal probability plot and a dotplot. Is it plausible that the population distribution is normal? 89. Construct a normal probability plot for the following sample of observations on coating thickness for low-viscosity paint (“Achieving a Target Value for a Manufacturing Process: A Case Study,” J. of Quality Technology, 1992: Observation pi Observation pi Observation pi .47 .0278 .77 .3611 .86 .6944 .58 .0833 .79 .4167 .89 .7500 .65 .1389 .80 .4722 .91 .8056 .69 .1944 .81 .5278 .95 .8611 .72 .2500 .82 .5833 1.01 .9167 .74 .3056 .84 .6389 1.04 .9722 Construct a Weibull probability plot and comment. 91. Construct a normal probability plot for the fatigue-crack propagation data given in Exercise 39 (Chapter 1). Does it appear plausible that propagation life has a normal distribution? Explain. 92. The article “The Load-Life Relationship for M50 Bearings with Silicon Nitride Ceramic Balls” (Lubrication Engr., 1984: 153–159) reports the accompanying data on bearing load life (million revs.) for bearings tested at a 6.45 kN load. 47.1 126.0 289.0 68.1 146.6 289.0 68.1 229.0 367.0 90.8 240.0 385.9 103.6 240.0 392.0 106.0 278.0 505.0 115.0 278.0 a. Construct a normal probability plot. Is normality plausible? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 188 CHAPTER 4 Continuous Random Variables and Probability Distributions b. Construct a Weibull probability plot. Is the Weibull distribution family plausible? 93. Construct a probability plot that will allow you to assess the plausibility of the lognormal distribution as a model for the rainfall data of Exercise 83 in Chapter 1. 94. The accompanying observations are precipitation values during March over a 30-year period in Minneapolis-St. Paul. .77 1.74 .81 1.20 1.95 1.20 .47 1.43 3.37 2.20 3.00 3.09 1.51 2.10 .52 1.62 1.31 .32 .59 .81 2.81 1.87 1.18 1.35 4.75 2.48 .96 1.89 .90 2.05 a. Construct and interpret a normal probability plot for this data set. b. Calculate the square root of each value and then construct a normal probability plot based on this transformed data. Does it seem plausible that the square root of precipitation is normally distributed? c. Repeat part (b) after transforming by cube roots. 95. Use a statistical software package to construct a normal probability plot of the tensile ultimate-strength data given in Exercise 13 of Chapter 1, and comment. 96. Let the ordered sample observations be denoted by y1, y2, c, yn ( y1 being the smallest and yn the largest). Our SUPPLEMENTARY EXERCISES 97. The following failure time observations (1000s of hours) resulted from accelerated life testing of 16 integrated circuit chips of a certain type: 82.8 242.0 229.9 11.6 26.5 558.9 359.5 244.8 366.7 502.5 304.3 204.6 307.8 379.1 179.7 212.6 Use the corresponding percentiles of the exponential distribution with l 5 1 to construct a probability plot. Then explain why the plot assesses the plausibility of the sample having been generated from any exponential distribution. (98–128) 98. Let X 5 the time it takes a read/write head to locate a desired record on a computer disk memory device once the head has been positioned over the correct track. If the disks rotate once every 25 millisec, a reasonable assumption is that X is uniformly distributed on the interval [0, 25]. a. Compute P(10 # X # 20). b. Compute P(X $ 10). c. Obtain the cdf F(X). d. Compute E(X) and sX. 99. A 12-in. bar that is clamped at both ends is to be subjected to an increasing amount of stress until it snaps. Let Y 5 the distance from the left end at which the break occurs. Suppose Y has pdf 1 y a bya1 2 b f(y) 5 • 24 12 0 suggested check for normality is to plot the (21((i 2 .5)/n), yi) pairs. Suppose we believe that the observations come from a distribution with mean 0, and let w1, c, wn be the ordered absolute values of the xirs . A half-normal plot is a probability plot of the wirs. More specifically, since P(u Z u # w) 5 P(2w # Z # w) 5 2(w) 2 1, a half-normal plot is a plot of the (21 5[(i 2 .5)/n 1 1]/26, wi) pairs. The virtue of this plot is that small or large outliers in the original sample will now appear only at the upper end of the plot rather than at both ends. Construct a half-normal plot for the following sample of measurement errors, and comment: 23.78, 21.27, 1.44, 2.39, 12.38, 243.40, 1.15, 23.96, 22.34, 30.84. e. The expected length of the shorter segment when the break occurs. 100. Let X denote the time to failure (in years) of a certain hydraulic component. Suppose the pdf of X is f(x) 5 32/(x 1 4)3 for x . 0. a. Verify that f(x) is a legitimate pdf. b. Determine the cdf. c. Use the result of part (b) to calculate the probability that time to failure is between 2 and 5 years. d. What is the expected time to failure? e. If the component has a salvage value equal to 100/(4 1 x) when its time to failure is x, what is the expected salvage value? 101. The completion time X for a certain task has cdf F(x) given by 0 # y # 12 otherwise Compute the following: a. The cdf of Y, and graph it. b. P(Y # 4), P(Y . 6), and P(4 # Y # 6) c. E(Y), E(Y2) , and V(Y) d. The probability that the break point occurs more than 2 in. from the expected break point. 0 x,0 ⎧ ⎪ x3 0#x,1 ⎪ 3 ⎪ ⎨ 1 7 7 3 7 ⎪ 1 2 2 a3 2 xb a4 2 4 xb 1 # x # 3 ⎪ 7 ⎪ 1 x. ⎩ 3 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Supplementary Exercises a. Obtain the pdf f(x) and sketch its graph. b. Compute P(.5 # X # 2). c. Compute E(X). 102. The breakdown voltage of a randomly chosen diode of a certain type is known to be normally distributed with mean value 40 V and standard deviation 1.5 V. a. What is the probability that the voltage of a single diode is between 39 and 42? b. What value is such that only 15% of all diodes have voltages exceeding that value? c. If four diodes are independently selected, what is the probability that at least one has a voltage exceeding 42? 103. The article “Computer Assisted Net Weight Control” (Quality Progress, 1983: 22–25) suggests a normal distribution with mean 137.2 oz and standard deviation 1.6 oz for the actual contents of jars of a certain type. The stated contents was 135 oz. a. What is the probability that a single jar contains more than the stated contents? b. Among ten randomly selected jars, what is the probability that at least eight contain more than the stated contents? c. Assuming that the mean remains at 137.2, to what value would the standard deviation have to be changed so that 95% of all jars contain more than the stated contents? 104. When circuit boards used in the manufacture of compact disc players are tested, the long-run percentage of defectives is 5%. Suppose that a batch of 250 boards has been received and that the condition of any particular board is independent of that of any other board. a. What is the approximate probability that at least 10% of the boards in the batch are defective? b. What is the approximate probability that there are exactly 10 defectives in the batch? 105. The article “Characterization of Room Temperature Damping in Aluminum-Indium Alloys” (Metallurgical Trans., 1993: 1611–1619) suggests that Al matrix grain size (mm) for an alloy consisting of 2% indium could be modeled with a normal distribution with a mean value 96 and standard deviation 14. a. What is the probability that grain size exceeds 100? b. What is the probability that grain size is between 50 and 80? c. What interval (a, b) includes the central 90% of all grain sizes (so that 5% are below a and 5% are above b)? 106. The reaction time (in seconds) to a certain stimulus is a continuous random variable with pdf 3# 1 1#x#3 f(x) 5 • 2 x 2 0 otherwise a. Obtain the cdf. b. What is the probability that reaction time is at most 2.5 sec? Between 1.5 and 2.5 sec? 189 c. Compute the expected reaction time. d. Compute the standard deviation of reaction time. e. If an individual takes more than 1.5 sec to react, a light comes on and stays on either until one further second has elapsed or until the person reacts (whichever happens first). Determine the expected amount of time that the light remains lit. [Hint: Let h(X) 5 the time that the light is on as a function of reaction time X.] 107. Let X denote the temperature at which a certain chemical reaction takes place. Suppose that X has pdf 1 (4 2 x 2) f(x) 5 • 9 0 21 # x # 2 otherwise a. Sketch the graph of f(x). b. Determine the cdf and sketch it. c. Is 0 the median temperature at which the reaction takes place? If not, is the median temperature smaller or larger than 0? d. Suppose this reaction is independently carried out once in each of ten different labs and that the pdf of reaction time in each lab is as given. Let Y 5 the number among the ten labs at which the temperature exceeds 1. What kind of distribution does Y have? (Give the names and values of any parameters.) 108. The article “Determination of the MTF of Positive Photoresists Using the Monte Carlo Method” (Photographic Sci. and Engr., 1983: 254–260) proposes the exponential distribution with parameter l 5 .93 as a model for the distribution of a photon’s free path length (mm) under certain circumstances. Suppose this is the correct model. a. What is the expected path length, and what is the standard deviation of path length? b. What is the probability that path length exceeds 3.0? What is the probability that path length is between 1.0 and 3.0? c. What value is exceeded by only 10% of all path lengths? 109. The article “The Prediction of Corrosion by Statistical Analysis of Corrosion Profiles” (Corrosion Science, 1985: 305–315) suggests the following cdf for the depth X of the deepest pit in an experiment involving the exposure of carbon manganese steel to acidified seawater. 2(x2a)/b F(x; a, b) 5 e2e 2` , x , ` The authors propose the values a 5 150 and b 5 90. Assume this to be the correct model. a. What is the probability that the depth of the deepest pit is at most 150? At most 300? Between 150 and 300? b. Below what value will the depth of the maximum pit be observed in 90% of all such experiments? c. What is the density function of X? d. The density function can be shown to be unimodal (a single peak). Above what value on the measurement axis does this peak occur? (This value is the mode.) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 190 CHAPTER 4 Continuous Random Variables and Probability Distributions e. It can be shown that E(X) < .5772b 1 a. What is the mean for the given values of a and b, and how does it compare to the median and mode? Sketch the graph of the density function. [Note: This is called the largest extreme value distribution.] 110. Let t = the amount of sales tax a retailer owes the government for a certain period. The article “Statistical Sampling in Tax Audits” (Statistics and the Law, 2008: 320–343) proposes modeling the uncertainty in t by regarding it as a normally distributed random variable with mean value m and standard deviation s (in the article, these two parameters are estimated from the results of a tax audit involving n sampled transactions). If a represents the amount the retailer is assessed, then an under-assessment results if t . a and an over-assessment results if a . t. The proposed penalty (i.e., loss) function for over- or under-assessment is L(a, t) 5 t a if t . a and 5 k(a t) if t # a (k . 1 is suggested to incorporate the idea that over-assessment is more serious than under-assessment). a. Show that a* 5 m 1 s21(1/(k 1 1)) is the value of a that minimizes the expected loss, where 21 is the inverse function of the standard normal cdf. b. If k = 2 (suggested in the article), m = $100,000, and s = $10,000, what is the optimal value of a, and what is the resulting probability of over-assessment? 111. The mode of a continuous distribution is the value x* that maximizes f(x). a. What is the mode of a normal distribution with parameters m and s? b. Does the uniform distribution with parameters A and B have a single mode? Why or why not? c. What is the mode of an exponential distribution with parameter l? (Draw a picture.) d. If X has a gamma distribution with parameters a and b, and a . 1, find the mode. [Hint: ln[f(x)] will be maximized iff f(x) is, and it may be simpler to take the derivative of ln[f(x)].] e. What is the mode of a chi-squared distribution having n degrees of freedom? 112. The article “Error Distribution in Navigation” (J. of the Institute of Navigation, 1971: 429–442) suggests that the frequency distribution of positive errors (magnitudes of errors) is well approximated by an exponential distribution. Let X 5 the lateral position error (nautical miles), which can be either negative or positive. Suppose the pdf of X is f(x) 5 (.1)e2.2|x| 2` , x , ` a. Sketch a graph of f(x) and verify that f(x) is a legitimate pdf (show that it integrates to 1). b. Obtain the cdf of X and sketch it. c. Compute P(X # 0), P(X # 2), P(21 # X # 2), and the probability that an error of more than 2 miles is made. 113. In some systems, a customer is allocated to one of two service facilities. If the service time for a customer served by facility i has an exponential distribution with parameter li (i 5 1, 2) and p is the proportion of all customers served by facility 1, then the pdf of X 5 the service time of a randomly selected customer is f(x; l1, l2, p) 5 e pl1e2l1x 1 (1 2 p)l2e2l2x 0 x$0 otherwise This is often called the hyperexponential or mixed exponential distribution. This distribution is also proposed as a model for rainfall amount in “Modeling Monsoon Affected Rainfall of Pakistan by Point Processes” (J. of Water Resources Planning and Mgmnt., 1992: 671–688). a. Verify that f(x; l1, l2, p) is indeed a pdf. b. What is the cdf F(x; l1, l2, p)? c. If X has f(x; l1, l2, p) as its pdf, what is E(X)? d. Using the fact that E(X 2) 5 2/l2 when X has an exponential distribution with parameter l, compute E(X 2) when X has pdf f(x; l1, l2, p). Then compute V(X). e. The coefficient of variation of a random variable (or distribution) is CV 5 s/m. What is CV for an exponential rv? What can you say about the value of CV when X has a hyperexponential distribution? f. What is CV for an Erlang distribution with parameters l and n as defined in Exercise 68? [Note: In applied work, the sample CV is used to decide which of the three distributions might be appropriate.] 114. Suppose a particular state allows individuals filing tax returns to itemize deductions only if the total of all itemized deductions is at least $5000. Let X (in 1000s of dollars) be the total of itemized deductions on a randomly chosen form. Assume that X has the pdf f(x; a) 5 e k/x a x$5 0 otherwise a. Find the value of k. What restriction on a is necessary? b. What is the cdf of X? c. What is the expected total deduction on a randomly chosen form? What restriction on a is necessary for E(X) to be finite? d. Show that ln(X/5) has an exponential distribution with parameter a 2 1. 115. Let Ii be the input current to a transistor and I0 be the output current. Then the current gain is proportional to ln(I0/Ii). Suppose the constant of proportionality is 1 (which amounts to choosing a particular unit of measurement), so that current gain 5 X 5 ln(I0/Ii). Assume X is normally distributed with m 5 1 and s 5 .05. a. What type of distribution does the ratio I0/Ii have? b. What is the probability that the output current is more than twice the input current? c. What are the expected value and variance of the ratio of output to input current? 116. The article “Response of SiCf/Si3N4 Composites Under Static and Cyclic Loading—An Experimental and Statistical Analysis” (J. of Engr. Materials and Technology, 1997: 186–193) suggests that tensile strength (MPa) of Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Supplementary Exercises composites under specified conditions can be modeled by a Weibull distribution with a 5 9 and b 5 180. a. Sketch a graph of the density function. b. What is the probability that the strength of a randomly selected specimen will exceed 175? Will be between 150 and 175? c. If two randomly selected specimens are chosen and their strengths are independent of one another, what is the probability that at least one has a strength between 150 and 175? d. What strength value separates the weakest 10% of all specimens from the remaining 90%? 117. Let Z have a standard normal distribution and define a new rv Y by Y 5 sZ 1 m. Show that Y has a normal distribution with parameters m and s. [Hint: Y # y iff Z # ? Use this to find the cdf of Y and then differentiate it with respect to y.] 118. a. Suppose the lifetime X of a component, when measured in hours, has a gamma distribution with parameters a and b. Let Y 5 the lifetime measured in minutes. Derive the pdf of Y. [Hint: Y # y iff X # y/60. Use this to obtain the cdf of Y and then differentiate to obtain the pdf.] b. If X has a gamma distribution with parameters a and b, what is the probability distribution of Y 5 cX? 119. In Exercises 117 and 118, as well as many other situations, one has the pdf f(x) of X and wishes to know the pdf of y 5 h(X). Assume that h( # ) is an invertible function, so that y 5 h(x) can be solved for x to yield x 5 k(y). Then it can be shown that the pdf of Y is posing some interesting questions regarding birth coincidences. a. Disregarding leap year and assuming that the other 365 days are equally likely, what is the probability that three randomly selected births all occur on March 11? Be sure to indicate what, if any, extra assumptions you are making. b. With the assumptions used in part (a), what is the probability that three randomly selected births all occur on the same day? c. The author suggested that, based on extensive data, the length of gestation (time between conception and birth) could be modeled as having a normal distribution with mean value 280 days and standard deviation 19.88 days. The due dates for the three Utah sisters were March 15, April 1, and April 4, respectively. Assuming that all three due dates are at the mean of the distribution, what is the probability that all births occurred on March 11? [Hint: The deviation of birth date from due date is normally distributed with mean 0.] d. Explain how you would use the information in part (c) to calculate the probability of a common birth date. 122. Let X denote the lifetime of a component, with f(x) and F(x) the pdf and cdf of X. The probability that the component fails in the interval (x, x 1 x) is approximately f(x) # x. The conditional probability that it fails in (x, x 1 x) given that it has lasted at least x is f(x) # x/[1 2 F(x)]. Dividing this by x produces the failure rate function: r(x) 5 g(y) 5 f [k(y)] # |kr(y)| a. If X has a uniform distribution with A 5 0 and B 5 1, derive the pdf of Y 5 2ln(X). b. Work Exercise 117, using this result. c. Work Exercise 118(b), using this result. 120. Based on data from a dart-throwing experiment, the article “Shooting Darts” (Chance, Summer 1997, 16–19) proposed that the horizontal and vertical errors from aiming at a point target should be independent of one another, each with a normal distribution having mean 0 and variance s2. It can then be shown that the pdf of the distance V from the target to the landing point is f(v) 5 v s2 # e2v /2s 2 2 v.0 a. This pdf is a member of what family introduced in this chapter? b. If s 5 20 mm (close to the value suggested in the paper), what is the probability that a dart will land within 25 mm (roughly 1 in.) of the target? 121. The article “Three Sisters Give Birth on the Same Day” (Chance, Spring 2001, 23–25) used the fact that three Utah sisters had all given birth on March 11, 1998 as a basis for 191 f(x) 1 2 F(x) An increasing failure rate function indicates that older components are increasingly likely to wear out, whereas a decreasing failure rate is evidence of increasing reliability with age. In practice, a “bathtub-shaped” failure is often assumed. a. If X is exponentially distributed, what is r(x)? b. If X has a Weibull distribution with parameters a and b, what is r(x)? For what parameter values will r(x) be increasing? For what parameter values will r(x) decrease with x? c. Since r(x) 5 2(d/dx)ln[1 2 F(x)], ln[1 2 F(x)] 5 2兰r(x)dx. Suppose r(x) 5 • x aa1 2 b b 0 0#x#b otherwise so that if a component lasts b hours, it will last forever (while seemingly unreasonable, this model can be used to study just “initial wearout”). What are the cdf and pdf of X? 123. Let U have a uniform distribution on the interval [0, 1]. Then observed values having this distribution can be obtained from a computer’s random number generator. Let X 5 2(1/l)ln(1 2 U). Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 192 CHAPTER 4 Continuous Random Variables and Probability Distributions a. Show that X has an exponential distribution with parameter l. [Hint: The cdf of X is F(x) 5 P(X # x); X # x is equivalent to U # ?] b. How would you use part (a) and a random number generator to obtain observed values from an exponential distribution with parameter l 5 10? 124. Consider an rv X with mean m and standard deviation s, and let g(X) be a specified function of X. The first-order Taylor series approximation to g(X) in the neighborhood of m is g(X) < g(m) 1 gr(m) # (X 2 m) The right-hand side of this equation is a linear function of X. If the distribution of X is concentrated in an interval over which g( )is approximately linear [e.g., 1x is approximately linear in (1, 2)], then the equation yields approximations to E(g(X)) and V(g(X)). a. Give expressions for these approximations. [Hint: Use rules of expected value and variance for a linear function aX 1 b.] b. If the voltage v across a medium is fixed but current I is random, then resistance will also be a random variable related to I by R 5 v/I. If mI 5 20 and sI 5 .5, calculate approximations to mR and sR. # 125. A function g(x) is convex if the chord connecting any two points on the function’s graph lies above the graph. When g(x) is differentiable, an equivalent condition is that for every x, the tangent line at x lies entirely on or below the graph. (See the figure below.) How does g(m) 5 g(E(X)) compare to E(g(X))? [Hint: The equation of the tangent line at x 5 m is y 5 g(m) 1 gr(m) # (x 2 m). Use the condition of convexity, substitute X for x, and take expected values. [Note: Unless g(x) is linear, the resulting inequality (usually called Jensen’s inequality) is strict (, rather than # ); it is valid for both continuous and discrete rv’s.] 126. Let X have a Weibull distribution with parameters a 5 2 and b. Show that Y 5 2X 2/b2 has a chi-squared distribution with n 5 2. [Hint: The cdf of Y is P(Y # y); express this probability in the form P(X # g(y)), use the fact that X has a cdf of the form in Expression (4.12), and differentiate with respect to y to obtain the pdf of Y.] 127. An individual’s credit score is a number calculated based on that person’s credit history that helps a lender determine how much he/she should be loaned or what credit limit should be established for a credit card. An article in the Los Angeles Times gave data which suggested that a beta distribution with parameters A 5 150, B 5 850, a 5 8, b 5 2 would provide a reasonable approximation to the distribution of American credit scores. [Note: credit scores are integer-valued]. a. Let X represent a randomly selected American credit score. What are the mean value and standard deviation of this random variable? What is the probability that X is within 1 standard deviation of its mean value? b. What is the approximate probability that a randomly selected score will exceed 750 (which lenders consider a very good score)? x 128. Let V denote rainfall volume and W denote runoff volume (both in mm). According to the article “Runoff Quality Analysis of Urban Catchments with Analytical Probability Models” (J. of Water Resource Planning and Management, 2006: 4–14), the runoff volume will be 0 if V # nd and will be k(V 2 nd) if V . nd. Here nd is the volume of depression storage (a constant), and k (also a constant) is the runoff coefficient. The cited article proposes an exponential distribution with parameter l for V. a. Obtain an expression for the cdf of W. [Note: W is neither purely continuous nor purely discrete; instead it has a “mixed” distribution with a discrete component at 0 and is continuous for values w . 0.] b. What is the pdf of W for w . 0? Use this to obtain an expression for the expected value of runoff volume. Bury, Karl, Statistical Distributions in Engineering, Cambridge Univ. Press, Cambridge, England, 1999. A readable and informative survey of distributions and their properties. Johnson, Norman, Samuel Kotz, and N. Balakrishnan, Continuous Univariate Distributions, vols. 1–2, Wiley, New York, 1994. These two volumes together present an exhaustive survey of various continuous distributions. Nelson, Wayne, Applied Life Data Analysis, Wiley, New York, 1982. Gives a comprehensive discussion of distributions and methods that are used in the analysis of lifetime data. Olkin, Ingram, Cyrus Derman, and Leon Gleser, Probability Models and Applications (2nd ed.), Macmillan, New York, 1994. Good coverage of general properties and specific distributions. Tangent line Bibliography Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5 Joint Probability Distributions and Random Samples INTRODUCTION In Chapters 3 and 4, we developed probability models for a single random variable. Many problems in probability and statistics involve several random variables simultaneously. In this chapter, we first discuss probability models for the joint (i.e., simultaneous) behavior of several random variables, putting special emphasis on the case in which the variables are independent of one another. We then study expected values of functions of several random variables, including covariance and correlation as measures of the degree of association between two variables. The last three sections of the chapter consider functions of n random variables X1, X2, . . ., Xn, focusing especially on their average (X1 . . . Xn)/n. We call any such function, itself a random variable, a statistic. Methods from probability are used to obtain information about the distribution of a statistic. The premier result of this type is the Central Limit Theorem (CLT), the basis for many inferential procedures involving large sample sizes. 193 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 194 CHAPTER 5 Joint Probability Distributions and Random Samples 5.1 Jointly Distributed Random Variables There are many experimental situations in which more than one random variable (rv) will be of interest to an investigator. We first consider joint probability distributions for two discrete rv’s, then for two continuous variables, and finally for more than two variables. Two Discrete Random Variables The probability mass function (pmf) of a single discrete rv X specifies how much probability mass is placed on each possible X value. The joint pmf of two discrete rv’s X and Y describes how much probability mass is placed on each possible pair of values (x, y). DEFINITION Let X and Y be two discrete rv’s defined on the sample space S of an experiment. The joint probability mass function p(x, y) is defined for each pair of numbers (x, y) by p(x, y) P(X x and Y y) It must be the case that p(x, y) 0 and g g p(x, y) 5 1. x y Now let A be any set consisting of pairs of (x, y) values (e.g., A {(x, y): x y 5} or {(x, y): max(x, y) 3}). Then the probability P[(X, Y) A] is obtained by summing the joint pmf over pairs in A: P[(X, Y) A] 5 Example 5.1 g g p(x, y) (x, y) A A large insurance agency services a number of customers who have purchased both a homeowner’s policy and an automobile policy from the agency. For each type of policy, a deductible amount must be specified. For an automobile policy, the choices are $100 and $250, whereas for a homeowner’s policy, the choices are 0, $100, and $200. Suppose an individual with both types of policy is selected at random from the agency’s files. Let X the deductible amount on the auto policy and Y the deductible amount on the homeowner’s policy. Possible (X, Y) pairs are then (100, 0), (100, 100), (100, 200), (250, 0), (250, 100), and (250, 200); the joint pmf specifies the probability associated with each one of these pairs, with any other pair having probability zero. Suppose the joint pmf is given in the accompanying joint probability table: p(x, y) x 100 250 0 y 100 200 .20 .05 .10 .15 .20 .30 Then p(100, 100) P(X 100 and Y 100) P($100 deductible on both policies) .10. The probability P(Y 100) is computed by summing probabilities of all (x, y) pairs for which y 100: P(Y 100) p(100, 100) p(250, 100) p(100, 200) p(250, 200) .75 ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.1 Jointly Distributed Random Variables 195 Once the joint pmf of the two variables X and Y is available, it is in principle straightforward to obtain the distribution of just one of these variables. As an example, let X and Y be the number of statistics and mathematics courses, respectively, currently being taken by a randomly selected statistics major. Suppose that we wish the distribution of X, and that when X 2, the only possible values of Y are 0, 1, and 2. Then pX(2) P(X 2) P[(X, Y) (2, 0) or (2, 1) or (2, 2)] p(2, 0) p(2, 1) p(2, 2) That is, the joint pmf is summed over all pairs of the form (2, y). More generally, for any possible value x of X, the probability pX (x) results from holding x fixed and summing the joint pmf p(x, y) over all y for which the pair (x, y) has positive probability mass. The same strategy applies to obtaining the distribution of Y by itself. DEFINITION The marginal probability mass function of X, denoted by pX (x), is given by pX(x) 5 g p(x, y) for each possible value x y: p(x, y).0 Similarly, the marginal probability mass function of Y is pY (y) 5 g p(x, y) for each possible value y. x: p(x, y).0 The use of the word marginal here is a consequence of the fact that if the joint pmf is displayed in a rectangular table as in Example 5.1, then the row totals give the marginal pmf of X and the column totals give the marginal pmf of Y. Once these marginal pmf’s are available, the probability of any event involving only X or only Y can be calculated. Example 5.2 (Example 5.1 continued) The possible X values are x 100 and x 250, so computing row totals in the joint probability table yields pX(100) p(100, 0) p(100, 100) p(100, 200) .50 and pX(250) p(250, 0) p(250, 100) p(250, 200) .50 The marginal pmf of X is then pX(x) 5 e .5 x 5 100, 250 0 otherwise Similarly, the marginal pmf of Y is obtained from column totals as .25 y 5 0, 100 pY (y) 5 • .50 y 5 200 0 otherwise so P(Y 100) pY(100) pY(200) .75 as before. ■ Two Continuous Random Variables The probability that the observed value of a continuous rv X lies in a onedimensional set A (such as an interval) is obtained by integrating the pdf f(x) over the set A. Similarly, the probability that the pair (X, Y) of continuous rv’s falls in Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 196 CHAPTER 5 Joint Probability Distributions and Random Samples a two-dimensional set A (such as a rectangle) is obtained by integrating a function called the joint density function. DEFINITION Let X and Y be continuous rv’s. A joint probability density function f(x, y) for these two variables is a function satisfying f(x, y) 0 and ` ` 冮2` 冮2` f(x, y) dx dy 5 1. Then for any two-dimensional set A P[(X, Y) A] 5 冮冮 f(x, y) dx dy A In particular, if A is the two-dimensional rectangle {(x, y): a x b, c y d}, then P[(X,Y) A] 5 P(a # X # b, c # Y # d) 5 b d 冮a 冮c f(x, y) dy dx We can think of f(x, y) as specifying a surface at height f(x, y) above the point (x, y) in a three-dimensional coordinate system. Then P[(X, Y) A] is the volume underneath this surface and above the region A, analogous to the area under a curve in the case of a single rv. This is illustrated in Figure 5.1. y f (x, y) Surface f (x, y) A Shaded rectangle Figure 5.1 Example 5.3 P[(X, Y ) A] volume under density surface above A A bank operates both a drive-up facility and a walk-up window. On a randomly selected day, let X the proportion of time that the drive-up facility is in use (at least one customer is being served or waiting to be served) and Y the proportion of time that the walk-up window is in use. Then the set of possible values for (X, Y ) is the rectangle D {(x, y): 0 x 1, 0 y 1}. Suppose the joint pdf of (X, Y) is given by 6 (x 1 y2) 0 # x # 1, 0 # y # 1 f (x, y) 5 • 5 0 otherwise To verify that this is a legitimate pdf, note that f(x, y) 0 and ` ` 6 (x 1 y2) dx dy 5 1 16 1 1 6 5 冮冮 x dx dy 1 冮冮 y2 dx dy 0 0 5 0 0 5 16 16 6 6 5 冮 x dx 1 冮 y2 dy 5 1 51 5 5 10 15 0 0 1 1 冮2` 冮2` f(x, y) dx dy 5 冮0 冮0 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.1 Jointly Distributed Random Variables 197 The probability that neither facility is busy more than one-quarter of the time is Pa0 # X # 1 1 ,0#Y# b 5 4 4 1/4 1/4 冮0 冮0 5 6 5 5 6 20 1/4 6 (x 1 y2) dx dy 5 1/4 冮0 冮0 x dx dy 1 x 2 x51/4 6 ` 1 2 x50 20 # # 6 5 1/4 1/4 冮0 冮0 y2 dx dy y3 y51/4 7 ` 5 3 y50 640 .0109 ■ The marginal pdf of each variable can be obtained in a manner analogous to what we did in the case of two discrete variables. The marginal pdf of X at the value x results from holding x fixed in the pair (x, y) and integrating the joint pdf over y. Integrating the joint pdf with respect to x gives the marginal pdf of Y. DEFINITION The marginal probability density functions of X and Y, denoted by fX(x) and fY(y), respectively, are given by ` fX(x) 5 冮2` f (x, y) dy fY (y) 5 冮2` f(x, y) dx for 2` , x , ` ` Example 5.4 (Example 5.3 continued for 2` , y , ` The marginal pdf of X, which gives the probability distribution of busy time for the drive-up facility without reference to the walk-up window, is fX(x) 5 冮 ` f (x, y) dy 5 2` 冮 1 0 6 6 2 (x 1 y2) dy 5 x 1 5 5 5 for 0 x 1 and 0 otherwise. The marginal pdf of Y is 6 2 3 y 1 0#y#1 5 fY(y) 5 • 5 0 otherwise Then 3 1 Pa # Y # b 5 4 4 3/4 冮1/4 fY (y) dy 5 37 5 .4625 80 ■ In Example 5.3, the region of positive joint density was a rectangle, which made computation of the marginal pdf’s relatively easy. Consider now an example in which the region of positive density is more complicated. Example 5.5 A nut company markets cans of deluxe mixed nuts containing almonds, cashews, and peanuts. Suppose the net weight of each can is exactly 1 lb, but the weight contribution of each type of nut is random. Because the three weights sum to 1, a joint probability model for any two gives all necessary information about the weight of the third type. Let X the weight of almonds in a selected can and Y the weight of cashews. Then the region of positive density is D {(x, y): 0 x 1, 0 y 1, x y 1}, the shaded region pictured in Figure 5.2. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 198 CHAPTER 5 Joint Probability Distributions and Random Samples y (0, 1) (x, 1 x) (1, 0) x Figure 5.2 x Region of positive density for Example 5.5 Now let the joint pdf for (X, Y) be f (x, y) 5 e 24xy 0 # x # 1, 0 # y # 1, x 1 y # 1 0 otherwise For any fixed x, f(x, y) increases with y; for fixed y, f(x, y) increases with x. This is appropriate because the word deluxe implies that most of the can should consist of almonds and cashews rather than peanuts, so that the density function should be large near the upper boundary and small near the origin. The surface determined by f(x, y) slopes upward from zero as (x, y) moves away from either axis. Clearly, f(x, y) 0. To verify the second condition on a joint pdf, recall that a double integral is computed as an iterated integral by holding one variable fixed (such as x as in Figure 5.2), integrating over values of the other variable lying along the straight line passing through the value of the fixed variable, and finally integrating over all possible values of the fixed variable. Thus 冮2` 冮2` f (x, y) dy dx 5 冮冮 f(x, y) dy dx 5 冮0 e 冮0 ` 1 ` D 1 5 冮0 24x e 12x y2 y512x ` f dx 5 2 y50 1 冮0 24xy dy f dx 12x(1 2 x)2 dx 5 1 To compute the probability that the two types of nuts together make up at most 50% of the can, let A {(x, y): 0 x 1, 0 y 1, and x y .5}, as shown in Figure 5.3. Then P((X, Y) A) 5 .5 .5 2 x 冮A 冮 f(x, y) dx dy 5 冮0 冮0 1 24xy dy dx 5 .0625 A Shaded region x .5 y 1 x y .5 x y .5 0 0 Figure 5.3 x .5 1 Computing P[(X, Y ) A] for Example 5.5 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.1 Jointly Distributed Random Variables 199 The marginal pdf for almonds is obtained by holding X fixed at x and integrating the joint pdf f(x, y) along the vertical line through x: 12x ` fX (x) 5 冮2` f(x, y) dy 5 • 冮0 24xy dy 5 12x(1 2 x)2 0#x#1 0 otherwise By symmetry of f(x, y) and the region D, the marginal pdf of Y is obtained by replacing x and X in fX(x) by y and Y, respectively. ■ Independent Random Variables In many situations, information about the observed value of one of the two variables X and Y gives information about the value of the other variable. In Example 5.1, the marginal probability of X at x 250 was .5, as was the probability that X 100. If, however, we are told that the selected individual had Y 0, then X 100 is four times as likely as X 250. Thus there is a dependence between the two variables. In Chapter 2, we pointed out that one way of defining independence of two events is via the condition P(A B) P(A) P(B). Here is an analogous definition for the independence of two rv’s. DEFINITION Two random variables X and Y are said to be independent if for every pair of x and y values p(x, y) pX (x) pY (y) when X and Y are discrete or (5.1) f(x, y) fX (x) fY (y) when X and Y are continuous If (5.1) is not satisfied for all (x, y), then X and Y are said to be dependent. The definition says that two variables are independent if their joint pmf or pdf is the product of the two marginal pmf’s or pdf’s. Intuitively, independence says that knowing the value of one of the variables does not provide additional information about what the value of the other variable might be. Example 5.6 In the insurance situation of Examples 5.1 and 5.2, p(100, 100) .10 ⬆ (.5)(.25) pX(100) pY(100) so X and Y are not independent. Independence of X and Y requires that every entry in the joint probability table be the product of the corresponding row and column marginal probabilities. ■ Example 5.7 (Example 5.5 continued) Because f(x, y) has the form of a product, X and Y would appear to be independent. However, although fX Q34R 5 fY Q34R 5 16 , f Q34 , 34R 5 0 2 16 # 16, so the variables are not in fact independent. To be independent, f (x, y) must have the form g(x) # h(y) and the region of positive density must be a rectangle whose sides are parallel to the coordinate axes. ■ 9 9 9 Independence of two random variables is most useful when the description of the experiment under study suggests that X and Y have no effect on one another. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 200 CHAPTER 5 Joint Probability Distributions and Random Samples Then once the marginal pmf’s or pdf’s have been specified, the joint pmf or pdf is simply the product of the two marginal functions. It follows that P(a X b, c Y d) P(a X b) P(c Y d) Example 5.8 Suppose that the lifetimes of two components are independent of one another and that the first lifetime, X1, has an exponential distribution with parameter l1, whereas the second, X2, has an exponential distribution with parameter l2. Then the joint pdf is f(x1, x2) fX1(x1) fX2(x2) 5 e l1e2l1x1 # l2e2l2x2 5 l1l2e2l1x12l2x2 x1 . 0, x2 . 0 0 otherwise Let l1 1/1000 and l2 1/1200, so that the expected lifetimes are 1000 hours and 1200 hours, respectively. The probability that both component lifetimes are at least 1500 hours is P(1500 X1, 1500 X2) P(1500 X1) P(1500 X2) e2l1(1500) # e2l2(1500) (.2231)(.2865) .0639 ■ More Than Two Random Variables To model the joint behavior of more than two random variables, we extend the concept of a joint distribution of two variables. DEFINITION If X1, X2, . . ., Xn are all discrete random variables, the joint pmf of the variables is the function p(x1, x2, . . . , xn) P(X1 x1, X2 x2, . . . , Xn xn) If the variables are continuous, the joint pdf of X1, . . ., Xn is the function f(x1, x2, . . ., xn) such that for any n intervals [a1, b1], . . . , [an, bn], P(a1 # X1 # b1, c, an # Xn # bn) 5 b1 冮a 1 bn c 冮 f (x1, c, xn) dxn cdx1 an In a binomial experiment, each trial could result in one of only two possible outcomes. Consider now an experiment consisting of n independent and identical trials, in which each trial can result in any one of r possible outcomes. Let pi P(outcome i on any particular trial), and define random variables by Xi the number of trials resulting in outcome i (i 1, . . . , r). Such an experiment is called a multinomial experiment, and the joint pmf of X1, . . . , Xr is called the multinomial distribution. By using a counting argument analogous to the one used in deriving the binomial distribution, the joint pmf of X1, . . . , Xr can be shown to be p(x1, . . . , xr) n! px1 # c# pxr r xi 5 0, 1, 2, c, with x11 c 1 xr 5 n (x !)(x !) 5 u 1 2 # c # (xr!) 1 0 otherwise The case r 2 gives the binomial distribution, with X1 number of successes and X2 n X1 number of failures. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.1 Jointly Distributed Random Variables Example 5.9 201 If the allele of each of ten independently obtained pea sections is determined and p1 P(AA), p2 P(Aa), p3 P(aa), X1 number of AAs, X2 number of Aas, and X3 number of aa’s, then the multinomial pmf for these Xi’s is p(x1, x2, x3) 5 10! px1px2px3 (x1!)(x2!)(x3!) 1 2 3 xi 5 0, 1, c and x1 1 x2 1 x3 5 10 With p1 p3 .25, p2 .5, P(X1 2, X2 5, X3 3) p(2, 5, 3) 5 Example 5.10 10! (.25)2(.5)5(.25)3 5 .0769 2! 5! 3! ■ When a certain method is used to collect a fixed volume of rock samples in a region, there are four resulting rock types. Let X1, X2, and X3 denote the proportion by volume of rock types 1, 2, and 3 in a randomly selected sample (the proportion of rock type 4 is 1 X1 X2 X3, so a variable X4 would be redundant). If the joint pdf of X1, X2, X3 is f(x1, x2, x3) 5 e kx1x2(1 2 x3) 0 # x1 # 1, 0 # x2 # 1, 0 # x3 # 1, x1 1 x2 1 x3 # 1 0 otherwise then k is determined by ` 冮0 e 冮0 1 5 ` ` 冮2` 冮2` 冮2` f (x1, x2, x3) dx3 dx2 dx1 15 1 2 x1 c 1 2 x1 2 x2 冮0 kx1x2(1 2 x3) dx3 d dx2 f dx1 This iterated integral has value k/144, so k 144. The probability that rocks of types 1 and 2 together account for at most 50% of the sample is 冮冮冮 P(X1 1 X2 # .5) 5 2, 3 E x 10 #x x1#x 1#for1, i51, x 1 x # .5 F f(x1, x2, x3) dx3 dx2 dx1 i 1 2 5 3 冮0 e 冮0 .5 .5 2 x1 1 c 2 1 2 x 1 2 x2 冮0 144x1x2(1 2 x3) dx3 d dx2 f dx1 .6066 ■ The notion of independence of more than two random variables is similar to the notion of independence of more than two events. DEFINITION The random variables X1, X2, . . . , Xn are said to be independent if for everysubset Xi1, Xi2, . . . , Xik of the variables (each pair, each triple, and so on), the joint pmf or pdf of the subset is equal to the product of the marginal pmf’s or pdf’s. Thus if the variables are independent with n 4, then the joint pmf or pdf of any two variables is the product of the two marginals, and similarly for any three variables and all four variables together. Most importantly, once we are told that n variables are independent, then the joint pmf or pdf is the product of the n marginals. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 202 CHAPTER 5 Joint Probability Distributions and Random Samples Example 5.11 If X1, . . . , Xn represent the lifetimes of n components, the components operate independently of one another, and each lifetime is exponentially distributed with parameter l, then for x1 0, x2 0, . . . , xn 0, f(x1, x2, c, xn) 5 (le2lx1) # (le2lx2) # c # (le2lxn) 5 lne2lg xi If these n components constitute a system that will fail as soon as a single component fails, then the probability that the system lasts past time t is P(X1 . t, c, Xn . t) 5 5 a 冮t 冮t ` ` ` c 冮 f(x1, c, xn) dx1cdxn t le2lx1 dx1 b ca 冮t ` le2lxn dxn b (elt)n enlt Therefore, P(system lifetime t) 1 enlt for t 0 which shows that system lifetime has an exponential distribution with parameter nl; the expected value of system lifetime is 1/nl. ■ In many experimental situations to be considered in this book, independence is a reasonable assumption, so that specifying the joint distribution reduces to deciding on appropriate marginal distributions. Conditional Distributions Suppose X the number of major defects in a randomly selected new automobile and Y the number of minor defects in that same auto. If we learn that the selected car has one major defect, what now is the probability that the car has at most three minor defects—that is, what is P(Y 3 | X 1)? Similarly, if X and Y denote the lifetimes of the front and rear tires on a motorcycle, and it happens that X 10,000 miles, what now is the probability that Y is at most 15,000 miles, and what is the expected lifetime of the rear tire “conditional on” this value of X? Questions of this sort can be answered by studying conditional probability distributions. DEFINITION Let X and Y be two continuous rv’s with joint pdf f(x, y) and marginal X pdf fX(x). Then for any X value x for which fX(x) 0, the conditional probability density function of Y given that X x is fY u X(y ux) 5 f (x, y) fX(x) 2` , y , ` If X and Y are discrete, replacing pdf’s by pmf’s in this definition gives the conditional probability mass function of Y when X x. Notice that the definition of fY | X(y | x) parallels that of P(B | A), the conditional probability that B will occur, given that A has occurred. Once the conditional pdf or pmf has been determined, questions of the type posed at the outset of this subsection can be answered by integrating or summing over an appropriate set of Y values. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.1 Jointly Distributed Random Variables Example 5.12 203 Reconsider the situation of Examples 5.3 and 5.4 involving X 5 the proportion of time that a bank’s drive-up facility is busy and Y the analogous proportion for the walk-up window. The conditional pdf of Y given that X .8 is fY u X (y u.8) 5 f(.8, y) 1.2(.8 1 y2) 1 5 5 (24 1 30y2) 0 , y , 1 fX (.8) 1.2(.8) 1 .4 34 The probability that the walk-up facility is busy at most half the time given that X .8 is then P(Y # .5 uX 5 .8) 5 .5 1 (24 1 30y2) dy 5 .390 34 .5 冮2` fY u X (y u.8) dy 5 冮0 Using the marginal pdf of Y gives P(Y .5) .350. Also E(Y) .6, whereas the expected proportion of time that the walk-up facility is busy given that X .8 (a conditional expectation) is E(Y uX 5 .8) 5 ` 冮2` y # fY u X (y u.8) dy 5 1 34 1 冮0 y(24 1 30y2) dy 5 .574 ■ If the two variables are independent, the marginal pmf or pdf in the denominator will cancel the corresponding factor in the numerator. The conditional distribution is then identical to the corresponding marginal distribution. EXERCISES Section 5.1 (1–21) 1. A service station has both self-service and full-service islands. On each island, there is a single regular unleaded pump with two hoses. Let X denote the number of hoses being used on the self-service island at a particular time, and let Y denote the number of hoses on the full-service island in use at that time. The joint pmf of X and Y appears in the accompanying tabulation. p(x, y) x 0 1 2 0 y 1 2 .10 .08 .06 .04 .20 .14 .02 .06 .30 a. What is P(X 1 and Y 1)? b. Compute P(X 1 and Y 1). c. Give a word description of the event {X ⬆ 0 and Y ⬆ 0}, and compute the probability of this event. d. Compute the marginal pmf of X and of Y. Using pX(x), what is P(X 1)? e. Are X and Y independent rv’s? Explain. 2. When an automobile is stopped by a roving safety patrol, each tire is checked for tire wear, and each headlight is checked to see whether it is properly aimed. Let X denote the number of headlights that need adjustment, and let Y denote the number of defective tires. a. If X and Y are independent with pX(0) .5, pX(1) .3, pX(2) .2, and pY (0) .6, pY (1) .1, pY(2) pY(3) .05, and pY (4) .2, display the joint pmf of (X, Y) in a joint probability table. b. Compute P(X 1 and Y 1) from the joint probability table, and verify that it equals the product P(X 1) # P(Y 1). c. What is P(X Y 0) (the probability of no violations)? d. Compute P(X Y 1). 3. A certain market has both an express checkout line and a superexpress checkout line. Let X1 denote the number of customers in line at the express checkout at a particular time of day, and let X2 denote the number of customers in line at the superexpress checkout at the same time. Suppose the joint pmf of X1 and X2 is as given in the accompanying table. x2 x1 0 1 2 3 4 0 1 2 3 .08 .06 .05 .00 .00 .07 .15 .04 .03 .01 .04 .05 .10 .04 .05 .00 .04 .06 .07 .06 a. What is P(X1 1, X2 1), that is, the probability that there is exactly one customer in each line? b. What is P(X1 X2), that is, the probability that the numbers of customers in the two lines are identical? c. Let A denote the event that there are at least two more customers in one line than in the other line. Express A in terms of X1 and X2, and calculate the probability of this event. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 204 CHAPTER 5 Joint Probability Distributions and Random Samples d. What is the probability that the total number of customers in the two lines is exactly four? At least four? 4. Return to the situation described in Exercise 3. a. Determine the marginal pmf of X1, and then calculate the expected number of customers in line at the express checkout. b. Determine the marginal pmf of X2. c. By inspection of the probabilities P(X1 4), P(X2 0), and P(X1 4, X2 0), are X1 and X2 independent random variables? Explain. 5. The number of customers waiting for gift-wrap service at a department store is an rv X with possible values 0, 1, 2, 3, 4 and corresponding probabilities .1, .2, .3, .25, .15. A randomly selected customer will have 1, 2, or 3 packages for wrapping with probabilities .6, .3, and .1, respectively. Let Y the total number of packages to be wrapped for the customers waiting in line (assume that the number of packages submitted by one customer is independent of the number submitted by any other customer). a. Determine P(X 3, Y 3), i.e., p(3, 3). b. Determine p(4, 11). 6. Let X denote the number of Canon digital cameras sold during a particular week by a certain store. The pmf of X is x 0 1 2 3 4 pX(x) .1 .2 .3 .25 .15 Sixty percent of all customers who purchase these cameras also buy an extended warranty. Let Y denote the number of purchasers during this week who buy an extended warranty. a. What is P(X 4, Y 2)? [Hint: This probability equals P(Y 2 | X 4) P(X 4); now think of the four purchases as four trials of a binomial experiment, with success on a trial corresponding to buying an extended warranty.] b. Calculate P(X Y). c. Determine the joint pmf of X and Y and then the marginal pmf of Y. 7. The joint probability distribution of the number X of cars and the number Y of buses per signal cycle at a proposed left-turn lane is displayed in the accompanying joint probability table. p(x, y) x 0 1 2 3 4 5 0 y 1 2 .025 .050 .125 .150 .100 .050 .015 .030 .075 .090 .060 .030 .010 .020 .050 .060 .040 .020 a. What is the probability that there is exactly one car and exactly one bus during a cycle? b. What is the probability that there is at most one car and at most one bus during a cycle? c. What is the probability that there is exactly one car during a cycle? Exactly one bus? d. Suppose the left-turn lane is to have a capacity of five cars, and that one bus is equivalent to three cars. What is the probability of an overflow during a cycle? e. Are X and Y independent rv’s? Explain. 8. A stockroom currently has 30 components of a certain type, of which 8 were provided by supplier 1, 10 by supplier 2, and 12 by supplier 3. Six of these are to be randomly selected for a particular assembly. Let X the number of supplier 1’s components selected, Y the number of supplier 2’s components selected, and p(x, y) denote the joint pmf of X and Y. a. What is p(3, 2)? [Hint: Each sample of size 6 is equally likely to be selected. Therefore, p(3, 2) (number of outcomes with X 3 and Y 2)/(total number of outcomes). Now use the product rule for counting to obtain the numerator and denominator.] b. Using the logic of part (a), obtain p(x, y). (This can be thought of as a multivariate hypergeometric distribution—sampling without replacement from a finite population consisting of more than two categories.) 9. Each front tire on a particular type of vehicle is supposed to be filled to a pressure of 26 psi. Suppose the actual air pressure in each tire is a random variable—X for the right tire and Y for the left tire, with joint pdf f(x, y) 5 e K(x 2 1 y2) 20 # x # 30, 20 # y # 30 0 otherwise a. What is the value of K? b. What is the probability that both tires are underfilled? c. What is the probability that the difference in air pressure between the two tires is at most 2 psi? d. Determine the (marginal) distribution of air pressure in the right tire alone. e. Are X and Y independent rv’s? 10. Annie and Alvie have agreed to meet between 5:00 P.M. and 6:00 P.M. for dinner at a local health-food restaurant. Let X Annie’s arrival time and Y Alvie’s arrival time. Suppose X and Y are independent with each uniformly distributed on the interval [5, 6]. a. What is the joint pdf of X and Y? b. What is the probability that they both arrive between 5:15 and 5:45? c. If the first one to arrive will wait only 10 min before leaving to eat elsewhere, what is the probability that they have dinner at the health-food restaurant? [Hint: The event of interest is A 5 E (x, y): | x 2 y | # 1 F .] 6 11. Two different professors have just submitted final exams for duplication. Let X denote the number of typographical errors on the first professor’s exam and Y denote the number of such errors on the second exam. Suppose X has a Poisson Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.1 Jointly Distributed Random Variables distribution with parameter m1, Y has a Poisson distribution with parameter m2, and X and Y are independent. a. What is the joint pmf of X and Y? b. What is the probability that at most one error is made on both exams combined? c. Obtain a general expression for the probability that the total number of errors in the two exams is m (where m is a nonnegative integer). [Hint: A {(x, y): x y m} {(m, 0), (m 1, 1), . . . , (1, m 1), (0, m)}. Now sum the joint pmf over (x, y) A and use the binomial theorem, which says that m g a ba kbm2k 5 (a 1 b)m k50 m k for any a, b.] 12. Two components of a minicomputer have the following joint pdf for their useful lifetimes X and Y: f(x, y) 5 e xe2x(11y) x $ 0 and y $ 0 0 otherwise a. What is the probability that the lifetime X of the first component exceeds 3? b. What are the marginal pdf’s of X and Y? Are the two lifetimes independent? Explain. c. What is the probability that the lifetime of at least one component exceeds 3? 13. You have two lightbulbs for a particular lamp. Let X the lifetime of the first bulb and Y the lifetime of the second bulb (both in 1000s of hours). Suppose that X and Y are independent and that each has an exponential distribution with parameter l 1. a. What is the joint pdf of X and Y? b. What is the probability that each bulb lasts at most 1000 hours (i.e., X 1 and Y 1)? c. What is the probability that the total lifetime of the two bulbs is at most 2? [Hint: Draw a picture of the region A {(x, y): x 0, y 0, x y 2} before integrating.] d. What is the probability that the total lifetime is between 1 and 2? 14. Suppose that you have ten lightbulbs, that the lifetime of each is independent of all the other lifetimes, and that each lifetime has an exponential distribution with parameter l. a. What is the probability that all ten bulbs fail before time t? b. What is the probability that exactly k of the ten bulbs fail before time t? c. Suppose that nine of the bulbs have lifetimes that are exponentially distributed with parameter l and that the remaining bulb has a lifetime that is exponentially distributed with parameter u (it is made by another manufacturer). What is the probability that exactly five of the ten bulbs fail before time t? 15. Consider a system consisting of three components as pictured. The system will continue to function as long as the 205 first component functions and either component 2 or component 3 functions. Let X1, X2, and X3 denote the lifetimes of components 1, 2, and 3, respectively. Suppose the Xi’s are independent of one another and each Xi has an exponential distribution with parameter l. 2 1 3 a. Let Y denote the system lifetime. Obtain the cumulative distribution function of Y and differentiate to obtain the pdf. [Hint: F(y) P(Y y); express the event {Y y} in terms of unions and/or intersections of the three events {X1 y}, {X2 y}, and {X3 y}.] b. Compute the expected system lifetime. 16. a. For f(x1, x2, x3) as given in Example 5.10, compute the joint marginal density function of X1 and X3 alone (by integrating over x2). b. What is the probability that rocks of types 1 and 3 together make up at most 50% of the sample? [Hint: Use the result of part (a).] c. Compute the marginal pdf of X1 alone. [Hint: Use the result of part (a).] 17. An ecologist wishes to select a point inside a circular sampling region according to a uniform distribution (in practice this could be done by first selecting a direction and then a distance from the center in that direction). Let X the x coordinate of the point selected and Y the y coordinate of the point selected. If the circle is centered at (0, 0) and has radius R, then the joint pdf of X and Y is 1 2 pR f(x, y) 5 u 0 x 2 1 y2 # R2 otherwise a. What is the probability that the selected point is within R/2 of the center of the circular region? [Hint: Draw a picture of the region of positive density D. Because f(x, y) is constant on D, computing a probability reduces to computing an area.] b. What is the probability that both X and Y differ from 0 by at most R/2? c. Answer part (b) for R/22 replacing R/2. d. What is the marginal pdf of X? Of Y? Are X and Y independent? 18. Refer to Exercise 1 and answer the following questions: a. Given that X 1, determine the conditional pmf of Y—i.e., pY | X (0 | 1), pY | X (1 | 1), and pY | X (2 | 1). b. Given that two hoses are in use at the self-service island, what is the conditional pmf of the number of hoses in use on the full-service island? c. Use the result of part (b) to calculate the conditional probability P(Y 1 | X 2). Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 206 CHAPTER 5 Joint Probability Distributions and Random Samples d. Given that two hoses are in use at the full-service island, what is the conditional pmf of the number in use at the self-service island? the color proportions are p1 .24, p2 .13, p3 .16, p4 .20, p5 .13, and p6 .14. a. If n 12, what is the probability that there are exactly two M&Ms of each color? b. For n 20, what is the probability that there are at most five orange candies? [Hint: Think of an orange candy as a success and any other color as a failure.] c. In a sample of 20 M&Ms, what is the probability that the number of candies that are blue, green, or orange is at least 10? 19. The joint pdf of pressures for right and left front tires is given in Exercise 9. a. Determine the conditional pdf of Y given that X x and the conditional pdf of X given that Y y. b. If the pressure in the right tire is found to be 22 psi, what is the probability that the left tire has a pressure of at least 25 psi? Compare this to P(Y 25). c. If the pressure in the right tire is found to be 22 psi, what is the expected pressure in the left tire, and what is the standard deviation of pressure in this tire? 21. Let X1, X2, and X3 be the lifetimes of components 1, 2, and 3 in a three-component system. a. How would you define the conditional pdf of X3 given that X1 x1 and X2 x2? b. How would you define the conditional joint pdf of X2 and X3 given that X1 x1? 20. Let X1, X2, X3, X4, X5, and X6 denote the numbers of blue, brown, green, orange, red, and yellow M&M candies, respectively, in a sample of size n. Then these Xi’s have a multinomial distribution. According to the M&M Web site, 5.2 Expected Values, Covariance, and Correlation Any function h(X) of a single rv X is itself a random variable. However, to compute E[h(X)], it is not necessary to obtain the probability distribution of h(X); instead, E[h(X)] is computed as a weighted average of h(x) values, where the weight function is the pmf p(x) or pdf f(x) of X. A similar result holds for a function h(X, Y) of two jointly distributed random variables. PROPOSITION Let X and Y be jointly distributed rv’s with pmf p(x, y) or pdf f(x, y) according to whether the variables are discrete or continuous. Then the expected value of a function h(X, Y), denoted by E[h(X, Y)] or mh(X, Y), is given by g g h(x, y) # p(x, y) E[h(X, Y )] 5 d Example 5.13 x ` if X and Y are discrete y ` 冮2` 冮2`h(x, y) # f(x, y) dx dy if X and Y are continuous Five friends have purchased tickets to a certain concert. If the tickets are for seats 1–5 in a particular row and the tickets are randomly distributed among the five, what is the expected number of seats separating any particular two of the five? Let X and Y denote the seat numbers of the first and second individuals, respectively. Possible (X, Y) pairs are {(1, 2), (1, 3), . . . , (5, 4)}, and the joint pmf of (X, Y) is 1 p(x, y) 5 u 20 0 x 5 1, c, 5; y 5 1, c, 5; x 2 y otherwise The number of seats separating the two individuals is h(X, Y) | X Y | 1. The accompanying table gives h(x, y) for each possible (x, y) pair. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.2 Expected Values, Covariance, and Correlation h(x, y) 1 2 3 4 5 y 1 2 x 3 4 5 — 0 1 2 3 0 — 0 1 2 1 0 — 0 1 2 1 0 — 0 3 2 1 0 — 207 Thus E[h(X, Y)] 5 b h(x, y) # p(x, y) 5 (x, y) 5 5 g g (u x 2 yu 2 1) # x51 y51 1 51 20 ■ x2y Example 5.14 In Example 5.5, the joint pdf of the amount X of almonds and amount Y of cashews in a 1-lb can of nuts was f(x, y) 5 e 24xy 0 # x # 1, 0 # y # 1, x 1 y # 1 0 otherwise If 1 lb of almonds costs the company $1.00, 1 lb of cashews costs $1.50, and 1 lb of peanuts costs $.50, then the total cost of the contents of a can is h(X, Y) (1)X (1.5)Y (.5)(1 X Y) .5 .5X Y (since 1 X Y of the weight consists of peanuts). The expected total cost is E[h(X, Y)] 5 5 ` ` 1 12x 冮2` 冮2` h(x, y) # f (x, y) dx dy 冮0 冮0 (.5 1 .5x 1 y) # 24xy dy dx 5 $1.10 ■ The method of computing the expected value of a function h(X1, . . . , Xn) of n random variables is similar to that for two random variables. If the Xi’s are discrete, E[h(X1, . . . , Xn)] is an n-dimensional sum; if the Xi’s are continuous, it is an ndimensional integral. Covariance When two random variables X and Y are not independent, it is frequently of interest to assess how strongly they are related to one another. DEFINITION The covariance between two rv’s X and Y is Cov(X, Y) E[(X mX)(Y mY)] g g (x 2 mX)(y 2 mY)p(x, y) 5 d x ` X, Y discrete y ` 冮2` 冮2`(x 2 mX)(y 2 mY)f (x, y) dx dy X, Y continuous Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 208 CHAPTER 5 Joint Probability Distributions and Random Samples That is, since X mX and Y mY are the deviations of the two variables from their respective mean values, the covariance is the expected product of deviations. Note that Cov(X, X) E[(X mX)2] V(X). The rationale for the definition is as follows. Suppose X and Y have a strong positive relationship to one another, by which we mean that large values of X tend to occur with large values of Y and small values of X with small values of Y. Then most of the probability mass or density will be associated with (x mX) and (y mY), either both positive (both X and Y above their respective means) or both negative, so the product (x mX)(y mY) will tend to be positive. Thus for a strong positive relationship, Cov(X, Y) should be quite positive. For a strong negative relationship, the signs of (x mX) and (y mY) will tend to be opposite, yielding a negative product. Thus for a strong negative relationship, Cov(X, Y) should be quite negative. If X and Y are not strongly related, positive and negative products will tend to cancel one another, yielding a covariance near 0. Figure 5.4 illustrates the different possibilities. The covariance depends on both the set of possible pairs and the probabilities. In Figure 5.4, the probabilities could be changed without altering the set of possible pairs, and this could drastically change the value of Cov(X, Y). y y y ␮Y ␮Y ␮Y x ␮X (a) x x ␮X (b) ␮X (c) Figure 5.4 p(x, y) 1/10 for each of ten pairs corresponding to indicated points: (a) positive covariance; (b) negative covariance; (c) covariance near zero Example 5.15 The joint and marginal pmf’s for X automobile policy deductible amount and Y homeowner policy deductible amount in Example 5.1 were p(x, y) x 100 250 0 y 100 200 x .20 .05 .10 .15 .20 .30 pX(x) 100 250 .5 .5 y 0 100 200 pY (y) .25 .25 .5 from which mX xpX(x) 175 and mY 125. Therefore, Cov(X, Y) 5 b (x 2 175)( y 2 125)p(x, y) (x, y) (100 175)(0 125)(.20) . . . (250 175)(200 125)(.30) 1875 ■ The following shortcut formula for Cov(X, Y) simplifies the computations. PROPOSITION Cov(X, Y) E(XY) mX mY Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.2 Expected Values, Covariance, and Correlation 209 According to this formula, no intermediate subtractions are necessary; only at the end of the computation is mX mY subtracted from E(XY). The proof involves expanding (X mX)(Y mY) and then taking the expected value of each term separately. Example 5.16 (Example 5.5 continued) The joint and marginal pdf’s of X amount of almonds and Y amount of cashews were f (x, y) 5 e 24xy 0 # x # 1, 0 # y # 1, x 1 y # 1 0 otherwise 12x(1 2 x)2 0 # x # 1 fX(x) 5 e 0 otherwise with fY ( y) obtained by replacing x by y in fX(x). It is easily verified that mX 5 mY 5 25, and ` E(XY) 5 1 ` 12x 冮2` 冮2` xy f (x, y) dx dy 5 冮0 冮0 xy # 24xy dy dx 1 2 5 8 冮 x 2(1 2 x)3 dx 5 15 0 2 2 4 2 Thus Cov(X, Y ) 5 15 . A negative covariance is rea2 A 25 BA 25 B 5 15 2 25 5 275 sonable here because more almonds in the can implies fewer cashews. ■ It might appear that the relationship in the insurance example is quite strong 2 since Cov(X, Y ) 1875, whereas Cov(X, Y) 5 275 in the nut example would seem to imply quite a weak relationship. Unfortunately, the covariance has a serious defect that makes it impossible to interpret a computed value. In the insurance example, suppose we had expressed the deductible amount in cents rather than in dollars. Then 100X would replace X, 100Y would replace Y, and the resulting covariance would be Cov(100X, 100Y) (100)(100)Cov(X, Y) 18,750,000. If, on the other hand, the deductible amount had been expressed in hundreds of dollars, the computed covariance would have been (.01)(.01)(1875) .1875. The defect of covariance is that its computed value depends critically on the units of measurement. Ideally, the choice of units should have no effect on a measure of strength of relationship. This is achieved by scaling the covariance. Correlation DEFINITION The correlation coefficient of X and Y, denoted by Corr(X, Y), rX,Y, or just r, is defined by rX, Y 5 Example 5.17 Cov(X, Y) sX # sY It is easily verified that in the insurance scenario of Example 5.15, E(X 2) 36,250, s2X 5 36,250 2 (175)2 5 5625, sX 75, E(Y 2) 22,500, s2Y 5 6875, and sY 82.92. This gives r5 1875 5 .301 (75)(82.92) ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 210 CHAPTER 5 Joint Probability Distributions and Random Samples The following proposition shows that r remedies the defect of Cov(X, Y ) and also suggests how to recognize the existence of a strong (linear) relationship. PROPOSITION 1. If a and c are either both positive or both negative, Corr(aX b, cY d) Corr(X, Y) 2. For any two rv’s X and Y, 1 Corr(X, Y) 1. Statement 1 says precisely that the correlation coefficient is not affected by a linear change in the units of measurement (if, say, X temperature in °C, then 9X/5 32 temperature in °F). According to Statement 2, the strongest possible positive relationship is evidenced by r 1, whereas the strongest possible negative relationship corresponds to r 1. The proof of the first statement is sketched in Exercise 35, and that of the second appears in Supplementary Exercise 87 at the end of the chapter. For descriptive purposes, the relationship will be described as strong if | r | .8, moderate if .5 |r| .8, and weak if | r | .5. If we think of p(x, y) or f (x, y) as prescribing a mathematical model for how the two numerical variables X and Y are distributed in some population (height and weight, verbal SAT score and quantitative SAT score, etc.), then r is a population characteristic or parameter that measures how strongly X and Y are related in the population. In Chapter 12, we will consider taking a sample of pairs (x1, y1), . . . , (xn, yn) from the population. The sample correlation coefficient r will then be defined and used to make inferences about r. The correlation coefficient r is actually not a completely general measure of the strength of a relationship. PROPOSITION 1. If X and Y are independent, then r 0, but r 0 does not imply independence. 2. r 1 or 1 iff Y aX b for some numbers a and b with a ⬆ 0. This proposition says that r is a measure of the degree of linear relationship between X and Y, and only when the two variables are perfectly related in a linear manner will r be as positive or negative as it can be. A r less than 1 in absolute value indicates only that the relationship is not completely linear, but there may still be a very strong nonlinear relation. Also, r 0 does not imply that X and Y are independent, but only that there is a complete absence of a linear relationship. When r 0, X and Y are said to be uncorrelated. Two variables could be uncorrelated yet highly dependent because there is a strong nonlinear relationship, so be careful not to conclude too much from knowing that r 0. Example 5.18 Let X and Y be discrete rv’s with joint pmf 1 p(x, y) 5 u 4 0 (x, y) 5 (24, 1), (4,21), (2, 2), (22, 22) otherwise Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.2 Expected Values, Covariance, and Correlation 211 The points that receive positive probability mass are identified on the (x, y) coordinate system in Figure 5.5. It is evident from the figure that the value of X is completely determined by the value of Y and vice versa, so the two variables are completely dependent. However, by symmetry m X m Y 0 and E(XY) 5 (24) 14 1 (24) 14 1 (4) 14 1 (4) 14 5 0 . The covariance is then Cov(X,Y) E(XY) mX mY 0 and thus rX,Y 0. Although there is perfect dependence, there is also complete absence of any linear relationship! 2 1 4 3 2 1 1 1 2 3 4 2 Figure 5.5 The population of pairs for Example 5.18 ■ A value of r near 1 does not necessarily imply that increasing the value of X causes Y to increase. It implies only that large X values are associated with large Y values. For example, in the population of children, vocabulary size and number of cavities are quite positively correlated, but it is certainly not true that cavities cause vocabulary to grow. Instead, the values of both these variables tend to increase as the value of age, a third variable, increases. For children of a fixed age, there is probably a low correlation between number of cavities and vocabulary size. In summary, association (a high correlation) is not the same as causation. EXERCISES Section 5.2 (22–36) 22. An instructor has given a short quiz consisting of two parts. For a randomly selected student, let X the number of points earned on the first part and Y the number of points earned on the second part. Suppose that the joint pmf of X and Y is given in the accompanying table. y p(x, y) x 0 5 10 0 5 10 15 .02 .04 .01 .06 .15 .15 .02 .20 .14 .10 .10 .01 a. If the score recorded in the grade book is the total number of points earned on the two parts, what is the expected recorded score E(X Y)? b. If the maximum of the two scores is recorded, what is the expected recorded score? 23. The difference between the number of customers in line at the express checkout and the number in line at the superexpress checkout in Exercise 3 is X1 X2. Calculate the expected difference. 24. Six individuals, including A and B, take seats around a circular table in a completely random fashion. Suppose the seats are numbered 1, . . . , 6. Let X A’s seat number and Y B’s seat number. If A sends a written message around the table to B in the direction in which they are closest, how many individuals (including A and B) would you expect to handle the message? 25. A surveyor wishes to lay out a square region with each side having length L. However, because of a measurement error, he instead lays out a rectangle in which the north–south sides both have length X and the east–west sides both have length Y. Suppose that X and Y are independent and that each is uniformly distributed on the interval [L A, L A] (where 0 A L). What is the expected area of the resulting rectangle? 26. Consider a small ferry that can accommodate cars and buses. The toll for cars is $3, and the toll for buses is $10. Let X and Y denote the number of cars and buses, respectively, carried on a single trip. Suppose the joint distribution of X and Y is as given in the table of Exercise 7. Compute the expected revenue from a single trip. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 212 CHAPTER 5 Joint Probability Distributions and Random Samples 27. Annie and Alvie have agreed to meet for lunch between noon (0:00 P.M.) and 1:00 P.M. Denote Annie’s arrival time by X, Alvie’s by Y, and suppose X and Y are independent with pdf’s 3x 2 0 # x # 1 fX (x) 5 e 0 otherwise fY ( y) 5 e 2y 0 # y # 1 0 otherwise What is the expected amount of time that the one who arrives first must wait for the other person? [Hint: h(X, Y ) | X Y | .] 28. Show that if X and Y are independent rv’s, then E(XY) E(X) E(Y). Then apply this in Exercise 25. [Hint: Consider the continuous case with f(x, y) fX (x) fY (y).] 32. Reconsider the minicomputer component lifetimes X and Y as described in Exercise 12. Determine E(XY). What can be said about Cov(X, Y) and r? 33. Use the result of Exercise 28 to show that when X and Y are independent, Cov(X, Y) Corr(X, Y) 0. 34. a. Recalling the definition of s2 for a single rv X, write a formula that would be appropriate for computing the variance of a function h(X, Y) of two random variables. [Hint: Remember that variance is just a special expected value.] b. Use this formula to compute the variance of the recorded score h(X, Y) [ max(X, Y)] in part (b) of Exercise 22. 29. Compute the correlation coefficient r for X and Y of Example 5.16 (the covariance has already been computed). 35. a. Use the rules of expected value to show that Cov(aX b, cY d) ac Cov(X, Y). b. Use part (a) along with the rules of variance and standard deviation to show that Corr(aX b, cY d) Corr(X, Y) when a and c have the same sign. c. What happens if a and c have opposite signs? 30. a. Compute the covariance for X and Y in Exercise 22. b. Compute r for X and Y in the same exercise. 36. Show that if Y aX b (a ⬆ 0), then Corr(X, Y) 1 or 1. Under what conditions will r 1? 31. a. Compute the covariance between X and Y in Exercise 9. b. Compute the correlation coefficient r for this X and Y. 5.3 Statistics and Their Distributions The observations in a single sample were denoted in Chapter 1 by x1, x2, . . . , xn. Consider selecting two different samples of size n from the same population distribution. The xi’s in the second sample will virtually always differ at least a bit from those in the first sample. For example, a first sample of n 3 cars of a particular type might result in fuel efficiencies x1 30.7, x2 29.4, x3 31.1, whereas a second sample may give x1 28.8, x2 30.0, and x3 32.5. Before we obtain data, there is uncertainty about the value of each xi. Because of this uncertainty, before the data becomes available we view each observation as a random variable and denote the sample by X1, X2, . . . , Xn (uppercase letters for random variables). This variation in observed values in turn implies that the value of any function of the sample observations—such as the sample mean, sample standard deviation, or sample fourth spread—also varies from sample to sample. That is, prior to obtaining x1, . . . , xn, there is uncertainty as to the value of x, the value of s, and so on. Example 5.19 Suppose that material strength for a randomly selected specimen of a particular type has a Weibull distribution with parameter values a 2 (shape) and b 5 (scale). The corresponding density curve is shown in Figure 5.6. Formulas from Section 4.5 give | 5 4.1628 s2 5 V(X) 5 5.365 s 5 2.316 m 5 E(x) 5 4.4311 m The mean exceeds the median because of the distribution’s positive skew. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.3 Statistics and Their Distributions 213 f(x) .15 .10 .05 x 0 0 5 Figure 5.6 10 15 The Weibull density curve for Example 5.19 We used statistical software to generate six different samples, each with n 10, from this distribution (material strengths for six different groups of ten specimens each). The results appear in Table 5.1, followed by the values of the sample mean, sample median, and sample standard deviation for each sample. Notice first that the ten observations in any particular sample are all different from those in any other sample. Second, the six values of the sample mean are all different from one another, as are the six values of the sample median and the six values of the sample standard deviation. The same is true of the sample 10% trimmed means, sample fourth spreads, and so on. Table 5.1 Samples from the Weibull Distribution of Example 5.19 Sample 1 2 3 4 5 6 1 2 3 4 5 6 7 8 9 10 x x| s 6.1171 4.1600 3.1950 0.6694 1.8552 5.2316 2.7609 10.2185 5.2438 4.5590 4.401 4.360 2.642 5.07611 6.79279 4.43259 8.55752 6.82487 7.39958 2.14755 8.50628 5.49510 4.04525 5.928 6.144 2.062 3.46710 2.71938 5.88129 5.14915 4.99635 5.86887 6.05918 1.80119 4.21994 2.12934 4.229 4.608 1.611 1.55601 4.56941 4.79870 2.49759 2.33267 4.01295 9.08845 3.25728 3.70132 5.50134 4.132 3.857 2.124 3.12372 6.09685 3.41181 1.65409 2.29512 2.12583 3.20938 3.23209 6.84426 4.20694 3.620 3.221 1.678 8.93795 3.92487 8.76202 7.05569 2.30932 5.94195 6.74166 1.75468 4.91827 7.26081 5.761 6.342 2.496 Furthermore, the value of the sample mean from any particular sample can be regarded as a point estimate (“point” because it is a single number, corresponding to a single point on the number line) of the population mean m, whose value is known to be 4.4311. None of the estimates from these six samples is identical to what is being estimated. The estimates from the second and sixth samples are much too large, whereas the fifth sample gives a substantial underestimate. Similarly, the sample standard deviation gives a point estimate of the population standard deviation. All six of the resulting estimates are in error by at least a small amount. In summary, the values of the individual sample observations vary from sample to sample, so will in general the value of any quantity computed from sample data, and the value of a sample characteristic used as an estimate of the corresponding population characteristic will virtually never coincide with what is being estimated. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 214 CHAPTER 5 Joint Probability Distributions and Random Samples DEFINITION A statistic is any quantity whose value can be calculated from sample data. Prior to obtaining data, there is uncertainty as to what value of any particular statistic will result. Therefore, a statistic is a random variable and will be denoted by an uppercase letter; a lowercase letter is used to represent the calculated or observed value of the statistic. Thus the sample mean, regarded as a statistic (before a sample has been selected or an experiment carried out), is denoted by X; the calculated value of this statistic is x. Similarly, S represents the sample standard deviation thought of as a statistic, and its computed value is s. If samples of two different types of bricks are selected and the individual compressive strengths are denoted by X1, . . . , Xm and Y1, . . . , Yn, respectively, then the statistic X Y, the difference between the two sample mean compressive strengths, is often of great interest. Any statistic, being a random variable, has a probability distribution. In particular, the sample mean X has a probability distribution. Suppose, for example, that n 2 components are randomly selected and the number of breakdowns while under warranty is determined for each one. Possible values for the sample mean number of breakdowns X are 0 (if X1 X2 0), .5 (if either X1 0 and X2 1 or X1 1 and X2 0), 1, 1.5, . . .. The probability distribution of X specifies P(X 0), P(X .5), and so on, from which other probabilities such as P(1 X 3) and P(X 2.5) can be calculated. Similarly, if for a sample of size n 2, the only possible values of the sample variance are 0, 12.5, and 50 (which is the case if X1 and X2 can each take on only the values 40, 45, or 50), then the probability distribution of S2 gives P(S2 0), P(S2 12.5), and P(S2 50). The probability distribution of a statistic is sometimes referred to as its sampling distribution to emphasize that it describes how the statistic varies in value across all samples that might be selected. Random Samples The probability distribution of any particular statistic depends not only on the population distribution (normal, uniform, etc.) and the sample size n but also on the method of sampling. Consider selecting a sample of size n 2 from a population consisting of just the three values 1, 5, and 10, and suppose that the statistic of interest is the sample variance. If sampling is done “with replacement,” then S2 0 will result if X1 X2. However, S2 cannot equal 0 if sampling is “without replacement.” So P(S2 0) 0 for one sampling method, and this probability is positive for the other method. Our next definition describes a sampling method often encountered (at least approximately) in practice. DEFINITION The rv’s X1, X2, . . . , Xn are said to form a (simple) random sample of size n if 1. The Xi’s are independent rv’s. 2. Every Xi has the same probability distribution. Conditions 1 and 2 can be paraphrased by saying that the Xi’s are independent and identically distributed (iid). If sampling is either with replacement or from an infinite (conceptual) population, Conditions 1 and 2 are satisfied exactly. These conditions will be approximately satisfied if sampling is without replacement, yet the sample size n is much smaller than the population size N. In practice, if n/N .05 (at most Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.3 Statistics and Their Distributions 215 5% of the population is sampled), we can proceed as if the Xi’s form a random sample. The virtue of this sampling method is that the probability distribution of any statistic can be more easily obtained than for any other sampling method. There are two general methods for obtaining information about a statistic’s sampling distribution. One method involves calculations based on probability rules, and the other involves carrying out a simulation experiment. Deriving a Sampling Distribution Probability rules can be used to obtain the distribution of a statistic provided that it is a “fairly simple” function of the Xi’s and either there are relatively few different X values in the population or else the population distribution has a “nice” form. Our next two examples illustrate such situations. Example 5.20 A certain brand of MP3 player comes in three configurations: a model with 2 GB of memory, costing $80, a 4 GB model priced at $100, and an 8 GB version with a price tag of $120. If 20% of all purchasers choose the 2 GB model, 30% choose the 4 GB model, and 50% choose the 8 GB model, then the probability distribution of the cost X of a single randomly selected MP3 player purchase is given by x 80 100 p(x) .2 .3 120 with m 106, s2 244 (5.2) .5 Suppose on a particular day only two MP3 players are sold. Let X1 the revenue from the first sale and X2 the revenue from the second. Suppose that X1 and X2 are independent, each with the probability distribution shown in (5.2) [so that X1 and X2 constitute a random sample from the distribution (5.2)]. Table 5.2 lists possible (x1, x2) pairs, the probability of each [computed using (5.2) and the assumption of independence], and the resulting x and s2 values. [Note that when n 2, s2 (x1 x )2 (x2 x )2.] Now to obtain the probability distribution of X, the sample average revenue per sale, we must consider each possible value x and compute its probability. For example, x 100 occurs three times in the table with probabilities .10, .09, and .10, so pX(100) P(X 100) .10 .09 .10 .29 Similarly, pS 2(800) P(S2 800) P(X1 80, X2 120 or X1 120, X2 80) .10 .10 .20 Table 5.2 Outcomes, Probabilities, and Values of x and s2 for Example 5.20 x1 80 80 80 100 100 100 120 120 120 x2 p(x1, x2) x s2 80 100 120 80 100 120 80 100 120 .04 .06 .10 .06 .09 .15 .10 .15 .25 80 90 100 90 100 110 100 110 120 0 200 800 200 0 200 800 200 0 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 216 CHAPTER 5 Joint Probability Distributions and Random Samples The complete sampling distributions of X and S2 appear in (5.3) and (5.4). x 80 90 100 110 120 pX(x) .04 .12 .29 .30 .25 0 200 800 .38 .42 .20 s2 2 2 pS (s ) (5.3) (5.4) Figure 5.7 pictures a probability histogram for both the original distribution (5.2) and the X distribution (5.3). The figure suggests first that the mean (expected value) of the X distribution is equal to the mean 106 of the original distribution, since both histograms appear to be centered at the same place. From (5.3), .5 .29 .30 .3 .25 .12 .2 .04 80 100 120 80 90 100 110 120 Figure 5.7 Probability histograms for the underlying distribution and X distribution in Example 5.20 mX E(X) g xpX(x) (80)(.04) . . . (120)(.25) 106 m Second, it appears that the X distribution has smaller spread (variability) than the original distribution, since probability mass has moved in toward the mean. Again from (5.3), s2X 5 V(X) 5 gx2 2 # pX(x) 2 m2X 5 (802)(.04) 1 c1 (1202)(.25) 2 (106)2 244 s2 5 122 5 5 2 2 The variance of X is precisely half that of the original variance (because n 2). Using (5.4), the mean value of S 2 is mS 2 E(S 2) gS 2 pS2(s2) (0)(.38) (200)(.42) (800)(.20) 244 s2 That is, the X sampling distribution is centered at the population mean m, and the S 2 sampling distribution is centered at the population variance s2. If there had been four purchases on the day of interest, the sample average revenue X would be based on a random sample of four Xi’s, each having the distribution (5.2). More calculation eventually yields the pmf of X for n 4 as x pX (x) 80 85 90 95 100 105 110 115 120 .0016 .0096 .0376 .0936 .1761 .2340 .2350 .1500 .0625 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.3 Statistics and Their Distributions 217 From this, mX 106 m and s2X 5 61 5 s2/4. Figure 5.8 is a probability histogram of this pmf. 80 90 100 110 120 Probability histogram for X based on n 4 in Example 5.20 Figure 5.8 Example 5.20 should suggest first of all that the computation of p X( x ) and pS2(s2) can be tedious. If the original distribution (5.2) had allowed for more than three possible values, then even for n 2 the computations would have been more involved. The example should also suggest, however, that there are some general relationships between E(X), V(X), E(S2), and the mean m and variance s2 of the original distribution. These are stated in the next section. Now consider an example in which the random sample is drawn from a continuous distribution. Example 5.21 Service time for a certain type of bank transaction is a random variable having an exponential distribution with parameter l. Suppose X1 and X2 are service times for two different customers, assumed independent of each other. Consider the total service time To X1 X2 for the two customers, also a statistic. The cdf of To is, for t 0, FT0(t) 5 P(X1 1 X2 # t) 5 t 5 t 2 x1 冮0 冮0 冮冮 f(x1, x2) dx1 dx2 5(x1, x2): x1 1 x2 #t6 le2lx1 # le2lx2 dx2 dx1 5 t 冮0 [le2lx 1 2 le2lt] dx1 1 elt ltelt The region of integration is pictured in Figure 5.9. x2 (x1, t x1) x1 x2 t x1 Figure 5.9 x1 Region of integration to obtain cdf of To in Example 5.21 The pdf of To is obtained by differentiating FTo(t): fTo(t) 5 e l2te2lt 0 t$0 t,0 (5.5) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 218 CHAPTER 5 Joint Probability Distributions and Random Samples This is a gamma pdf (a 2 and b 1/l). The pdf of X To /2 is obtained from the relation {X x} iff {To 2x} as fX(x) 5 e 4l2 xe22lx 0 x$0 x,0 (5.6) The mean and variance of the underlying exponential distribution are m 1/l and s2 1/l2. From Expressions (5.5) and (5.6), it can be verified that E(X) 1/l, V(X) 1/(2l2), E(To) 2/l, and V(To) 2/l2. These results again suggest some general relationships between means and variances of X, To, and the underlying distribution. Simulation Experiments The second method of obtaining information about a statistic’s sampling distribution is to perform a simulation experiment. This method is usually used when a derivation via probability rules is too difficult or complicated to be carried out. Such an experiment is virtually always done with the aid of a computer. The following characteristics of an experiment must be specified: 1. The statistic of interest (X, S, a particular trimmed mean, etc.) 2. The population distribution (normal with m 100 and s 15, uniform with lower limit A 5 and upper limit B 10, etc.) 3. The sample size n (e.g., n 10 or n 50) 4. The number of replications k (number of samples to be obtained) Then use appropriate software to obtain k different random samples, each of size n, from the designated population distribution. For each sample, calculate the value of the statistic and construct a histogram of the k values. This histogram gives the approximate sampling distribution of the statistic. The larger the value of k, the better the approximation will tend to be (the actual sampling distribution emerges as k ). In practice, k 500 or 1000 is usually sufficient if the statistic is “fairly simple.” B Example 5.22 The population distribution for our first simulation study is normal with m 8.25 and s .75, as pictured in Figure 5.10. [The article “Platelet Size in Myocardial Infarction” (British Med. J., 1983: 449–451) suggests this distribution for platelet volume in individuals with no history of serious heart problems.] ␴ .75 6.00 6.75 7.50 9.00 9.75 10.50 ␮ 8.25 Figure 5.10 Normal distribution, with m 8.25 and s .75 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.3 Statistics and Their Distributions 219 We actually performed four different experiments, with 500 replications for each one. In the first experiment, 500 samples of n 5 observations each were generated using Minitab, and the sample sizes for the other three were n 10, n 20, and n 30, respectively. The sample mean was calculated for each sample, and the resulting histograms of x values appear in Figure 5.11. Relative frequency Relative frequency .25 .25 .20 .20 .15 .15 .10 .10 .05 .05 x x 7.50 7.80 8.10 8.40 8.70 7.65 7.95 8.25 8.55 8.85 (b) 7.35 7.65 7.95 8.25 8.55 8.85 9.15 7.50 7.80 8.10 8.40 8.70 9.00 9.30 (a) Relative frequency Relative frequency .25 .25 .20 .20 .15 .15 .10 .10 .05 .05 x 7.80 8.10 8.40 8.70 7.95 8.25 8.55 (c) x 7.80 8.10 8.40 8.70 7.95 8.25 8.55 (d) Figure 5.11 Sample histograms for x based on 500 samples, each consisting of n observations: (a) n 5; (b) n 10; (c) n 20; (d) n 30 The first thing to notice about the histograms is their shape. To a reasonable approximation, each of the four looks like a normal curve. The resemblance would be even more striking if each histogram had been based on many more than 500 x values. Second, each histogram is centered approximately at 8.25, the mean of the population being sampled. Had the histograms been based on an unending sequence of x values, their centers would have been exactly the population mean, 8.25. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 220 CHAPTER 5 Joint Probability Distributions and Random Samples The final aspect of the histograms to note is their spread relative to one another. The larger the value of n, the more concentrated is the sampling distribution about the mean value. This is why the histograms for n 20 and n 30 are based on narrower class intervals than those for the two smaller sample sizes. For the larger sample sizes, most of the x values are quite close to 8.25. This is the effect of averaging. When n is small, a single unusual x value can result in an x value far from the center. With a larger sample size, any unusual x values, when averaged in with the other sample values, still tend to yield an x value close to m. Combining these insights yields a result that should appeal to your intuition: X based on a large n tends to be closer to m than does X based on a small n. Example 5.23 Consider a simulation experiment in which the population distribution is quite skewed. Figure 5.12 shows the density curve for lifetimes of a certain type of electronic control [this is actually a lognormal distribution with E(ln(X)) 3 and V(ln(X)) .16]. Again the statistic of interest is the sample mean X. The experiment utilized 500 replications and considered the same four sample sizes as in Example 5.22. The resulting histograms along with a normal probability plot from Minitab for the 500 x values based on n 30 are shown in Figure 5.13. f(x) .05 .04 .03 .02 .01 x 0 25 50 75 Figure 5.12 Density curve for the simulation experiment of Example 5.23 [E(X) 21.7584, V(X) 82.1449] Unlike the normal case, these histograms all differ in shape. In particular, they become progressively less skewed as the sample size n increases. The average of the 500 x values for the four different sample sizes are all quite close to the mean value of the population distribution. If each histogram had been based on an unending sequence of x values rather than just 500, all four would have been centered at exactly 21.7584. Thus different values of n change the shape but not the center of the sampling distribution of X. Comparison of the four histograms in Figure 5.13 also shows that as n increases, the spread of the histograms decreases. Increasing n results in a greater degree of concentration about the population mean value and makes the histogram look more like a normal curve. The histogram of Figure 5.13(d) and the normal probability plot in Figure 5.13(e) provide convincing evidence that a sample size of n 30 is sufficient to overcome the skewness of the population distribution and give an approximately normal X sampling distribution. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.3 Statistics and Their Distributions Density 221 Density .10 .10 n=5 n = 10 .05 .05 0 0 x 10 20 30 40 x 10 20 30 (a) 40 (b) Density Density .2 .2 n = 20 n = 30 .1 .1 0 0 x 15 20 25 x 15 (c) 20 25 (d) (e) Figure 5.13 Results of the simulation experiment of Example 5.23: (a) x histogram for n 5; (b) x histogram for n 10; (c) x histogram for n 20; (d) x histogram for n 30; (e) normal probability plot for n 30 (from Minitab) ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 222 Joint Probability Distributions and Random Samples CHAPTER 5 EXERCISES Section 5.3 (37–45) 37. A particular brand of dishwasher soap is sold in three sizes: 25 oz, 40 oz, and 65 oz. Twenty percent of all purchasers select a 25-oz box, 50% select a 40-oz box, and the remaining 30% choose a 65-oz box. Let X1 and X2 denote the package sizes selected by two independently selected purchasers. a. Determine the sampling distribution of X, calculate E(X), and compare to m. b. Determine the sampling distribution of the sample variance S2, calculate E(S2), and compare to s2. 38. There are two traffic lights on a commuter’s route to and from work. Let X1 be the number of lights at which the commuter must stop on his way to work, and X2 be the number of lights at which he must stop when returning from work. Suppose these two variables are independent, each with pmf given in the accompanying table (so X1, X2 is a random sample of size n 2). x1 0 1 2 p(x1) .2 .5 .3 m 1.1, s2 .49 a. Determine the pmf of To X1 X2. b. Calculate mTo. How does it relate to m, the population mean? c. Calculate sT2o. How does it relate to s2, the population variance? d. Let X3 and X4 be the number of lights at which a stop is required when driving to and from work on a second day assumed independent of the first day. With To the sum of all four Xi’s, what now are the values of E(To) and V(To)? e. Referring back to (d), what are the values of P(To 8) and P(To 7) [Hint: Don’t even think of listing all possible outcomes!] 39. It is known that 80% of all brand A zip drives work in a satisfactory manner throughout the warranty period (are “successes”). Suppose that n 10 drives are randomly selected. Let X the number of successes in the sample. The statistic X/n is the sample proportion (fraction) of successes. Obtain the sampling distribution of this statistic. [Hint: One possible value of X/n is .3, corresponding to X 3. What is the probability of this value (what kind of random variable is X)?] 40. A box contains ten sealed envelopes numbered 1, . . . , 10. The first five contain no money, the next three each contains $5, and there is a $10 bill in each of the last two. A sample of size 3 is selected with replacement (so we have a random sample), and you get the largest amount in any of the envelopes selected. If X1, X2, and X3 denote the amounts in the selected envelopes, the statistic of interest is M the maximum of X1, X2, and X3. a. Obtain the probability distribution of this statistic. b. Describe how you would carry out a simulation experiment to compare the distributions of M for various sample sizes. How would you guess the distribution would change as n increases? 41. Let X be the number of packages being mailed by a randomly selected customer at a certain shipping facility. Suppose the distribution of X is as follows: x 1 2 3 4 p(x) .4 .3 .2 .1 a. Consider a random sample of size n 2 (two customers), and let X be the sample mean number of packages shipped. Obtain the probability distribution of X. b. Refer to part (a) and calculate P(X 2.5). c. Again consider a random sample of size n 2, but now focus on the statistic R the sample range (difference between the largest and smallest values in the sample). Obtain the distribution of R. [Hint: Calculate the value of R for each outcome and use the probabilities from part (a).] d. If a random sample of size n 4 is selected, what is P(X 1.5)? [Hint: You should not have to list all possible outcomes, only those for which x 1.5.] 42. A company maintains three offices in a certain region, each staffed by two employees. Information concerning yearly salaries (1000s of dollars) is as follows: Office Employee Salary 1 1 29.7 1 2 33.6 2 3 30.2 2 4 33.6 3 5 25.8 3 6 29.7 a. Suppose two of these employees are randomly selected from among the six (without replacement). Determine the sampling distribution of the sample mean salary X. b. Suppose one of the three offices is randomly selected. Let X1 and X2 denote the salaries of the two employees. Determine the sampling distribution of X. c. How does E(X) from parts (a) and (b) compare to the population mean salary m? 43. Suppose the amount of liquid dispensed by a certain machine is uniformly distributed with lower limit A 8 oz and upper limit B 10 oz. Describe how you would carry out simulation experiments to compare the sampling distribution of the (sample) fourth spread for sample sizes n 5, 10, 20, and 30. 44. Carry out a simulation experiment using a statistical computer package or other software to study the sampling distribution of X when the population distribution is Weibull with a 2 and b 5, as in Example 5.19. Consider the four sample sizes n 5, 10, 20, and 30, and in each case use 1000 replications. For which of these sample sizes does the X sampling distribution appear to be approximately normal? 45. Carry out a simulation experiment using a statistical computer package or other software to study the sampling distribution of X when the population distribution is lognormal with E(ln(X)) 3 and V(ln(X)) 1. Consider the four sample sizes n 10, 20, 30, and 50, and in each case use 1000 replications. For which of these sample sizes does the X sampling distribution appear to be approximately normal? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.4 The Distribution of the Sample Mean 223 5.4 The Distribution of the Sample Mean The importance of the sample mean X springs from its use in drawing conclusions about the population mean m. Some of the most frequently used inferential procedures are based on properties of the sampling distribution of X. A preview of these properties appeared in the calculations and simulation experiments of the previous section, where we noted relationships between E(X) and m and also among V(X), s2, and n. PROPOSITION Let X1, X2, . . . , Xn be a random sample from a distribution with mean value m and standard deviation s. Then 1. E(X) mX m 2. V( X ) 5 s 2X 5 s2/n and sX 5 s/ 1n In addition, with To X1 . . . Xn (the sample total), E(To) nm, V(To) ns2, and sTo 5 1ns. Proofs of these results are deferred to the next section. According to Result 1, the sampling (i.e., probability) distribution of X is centered precisely at the mean of the population from which the sample has been selected. Result 2 shows that the X distribution becomes more concentrated about m as the sample size n increases. In marked contrast, the distribution of To becomes more spread out as n increases. Averaging moves probability in toward the middle, whereas totaling spreads probability out over a wider and wider range of values. The standard deviation sX 5 s/ 1n is often called the standard error of the mean; it describes the magnitude of a typical or representative deviation of the sample mean from the population mean. Example 5.24 In a notched tensile fatigue test on a titanium specimen, the expected number of cycles to first acoustic emission (used to indicate crack initiation) is m 28,000, and the standard deviation of the number of cycles is s 5000. Let X1, X2, . . . , X25 be a random sample of size 25, where each Xi is the number of cycles on a different randomly selected specimen. Then the expected value of the sample mean number of cycles until first emission is E(X) m 28,000, and the expected total number of cycles for the 25 specimens is E(T0) nm 25(28,000) 700,000. The standard deviation of X (standard error of the mean) and of T0 are 5000 5 1000 125 sTo 5 1ns 5 125(5000) 5 25,000 sX 5 s/ 1n 5 If the sample size increases to n 100, E(X) is unchanged, but sX 500, half of its previous value (the sample size must be quadrupled to halve the standard deviation of X ). ■ The Case of a Normal Population Distribution The simulation experiment of Example 5.22 indicated that when the population distribution is normal, each histogram of x values is well approximated by a normal curve. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 224 CHAPTER 5 Joint Probability Distributions and Random Samples PROPOSITION Let X1, X2, . . . , Xn be a random sample from a normal distribution with mean m and standard deviation s. Then for any n, X is normally distributed (with mean m and standard deviation s/ 1n), as is To (with mean nm and standard deviation 1ns).* We know everything there is to know about the X and To distributions when the population distribution is normal. In particular, probabilities such as P(a X b) and P(c To d) can be obtained simply by standardizing. Figure 5.14 illustrates the proposition. X distribution when n 10 X distribution when n 4 Population distribution Figure 5.14 Example 5.25 A normal population distribution and X sampling distributions The time that it takes a randomly selected rat of a certain subspecies to find its way through a maze is a normally distributed rv with m 1.5 min and s .35 min. Suppose five rats are selected. Let X1, . . . , X5 denote their times in the maze. Assuming the Xi’s to be a random sample from this normal distribution, what is the probability that the total time To X1 . . . X5 for the five is between 6 and 8 min? By the proposition, To has a normal distribution with mTo nm 5(1.5) 7.5 and variance s2To 5 ns2 5 5(.1225) 5 .6125, so sTo .783. To standardize To, subtract mTo and divide by sTo: 6 2 7.5 8 2 7.5 #Z# b .783 .783 P(6 # To # 8) 5 Pa P(1.92 Z .64) (.64) (1.92) .7115 Determination of the probability that the sample average time X (a normally distributed variable) is at most 2.0 min requires mX m 1.5 and sX 5 s/ 1n 5 .35/ 15 5 .1565. Then P(X # 2.0) 5 PaZ # 2.0 2 1.5 b 5 P(Z # 3.19) 5 .1565 (3.19) 5 .9993 ■ * A proof of the result for To when n 2 is possible using the method in Example 5.21, but the details are messy. The general result is usually proved using a theoretical tool called a moment generating function. One of the chapter references can be consulted for more information. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.4 The Distribution of the Sample Mean 225 The Central Limit Theorem When the Xi’s are normally distributed, so is X for every sample size n. The derivations in Example 5.20 and simulation experiment of Example 5.23 suggest that even when the population distribution is highly nonnormal, averaging produces a distribution more bell-shaped than the one being sampled. A reasonable conjecture is that if n is large, a suitable normal curve will approximate the actual distribution of X. The formal statement of this result is the most important theorem of probability. THEOREM The Central Limit Theorem (CLT) Let X1, X2, . . . , Xn be a random sample from a distribution with mean m and variance s2. Then if n is sufficiently large, X has approximately a normal distribution with mX m and s2X 5 s2/n, and To also has approximately a normal distribution with mTo nm, s2To 5 ns2. The larger the value of n, the better the approximation. Figure 5.15 illustrates the Central Limit Theorem. According to the CLT, when n is large and we wish to calculate a probability such as P(a X b), we need only “pretend” that X is normal, standardize it, and use the normal table. The resulting answer will be approximately correct. The exact answer could be obtained only by first finding the distribution of X, so the CLT provides a truly impressive shortcut. The proof of the theorem involves much advanced mathematics. X distribution for large n (approximately normal) X distribution for small to moderate n Population distribution ␮ Figure 5.15 Example 5.26 The Central Limit Theorem illustrated The amount of a particular impurity in a batch of a certain chemical product is a random variable with mean value 4.0 g and standard deviation 1.5 g. If 50 batches are independently prepared, what is the (approximate) probability that the sample average amount of impurity X is between 3.5 and 3.8 g? According to the rule of thumb to be stated shortly, n 50 is large enough for the CLT to be applicable. X then has approximately a normal distribution with mean value mX 4.0 and sX 5 1.5/ 150 5 .2121, so 3.5 2 4.0 3.8 2 4.0 P(3.5 # X # 3.8) < Pa #Z# b .2121 .2121 (.94) (2.36) .1645 ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 226 CHAPTER 5 Joint Probability Distributions and Random Samples Example 5.27 A certain consumer organization customarily reports the number of major defects for each new automobile that it tests. Suppose the number of such defects for a certain model is a random variable with mean value 3.2 and standard deviation 2.4. Among 100 randomly selected cars of this model, how likely is it that the sample average number of major defects exceeds 4? Let Xi denote the number of major defects for the ith car in the random sample. Notice that Xi is a discrete rv, but the CLT is applicable whether the variable of interest is discrete or continuous. Also, although the fact that the standard deviation of this nonnegative variable is quite large relative to the mean value suggests that its distribution is positively skewed, the large sample size implies that X does have approximately a normal distribution. Using mX 3.2 and sX .24, P(X . 4) < PaZ . 4 2 3.2 b 512 .24 (3.33) 5 .0004 ■ The CLT provides insight into why many random variables have probability distributions that are approximately normal. For example, the measurement error in a scientific experiment can be thought of as the sum of a number of underlying perturbations and errors of small magnitude. A practical difficulty in applying the CLT is in knowing when n is sufficiently large. The problem is that the accuracy of the approximation for a particular n depends on the shape of the original underlying distribution being sampled. If the underlying distribution is close to a normal density curve, then the approximation will be good even for a small n, whereas if it is far from being normal, then a large n will be required. Rule of Thumb If n 30, the Central Limit Theorem can be used. There are population distributions for which even an n of 40 or 50 does not suffice, but such distributions are rarely encountered in practice. On the other hand, the rule of thumb is often conservative; for many population distributions, an n much less than 30 would suffice. For example, in the case of a uniform population distribution, the CLT gives a good approximation for n 12. Example 5.28 Consider the distribution shown in Figure 5.16 for the amount purchased (rounded to the nearest dollar) by a randomly selected customer at a particular gas station (a similar distribution for purchases in Britain (in £) appeared in the article “Data Mining for Fun and Profit,” Statistical Science, 2000: 111–131; there were big spikes at the values, 10, 15, 20, 25, and 30). The distribution is obviously quite non-normal. We asked Minitab to select 1000 different samples, each consisting of n 15 observations, and calculate the value of the sample mean X for each one. Figure 5.17 is a histogram of the resulting 1000 values; this is the approximate sampling distribution of X under the specified circumstances. This distribution is clearly approximately normal even though the sample size is actually much smaller than Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.4 The Distribution of the Sample Mean 227 Probability 0.16 0.14 0.12 0.10 0.08 0.06 0.04 0.02 Purchase amount 0.00 5 10 15 Figure 5.16 20 25 30 35 40 45 50 55 60 Probability distribution of X amount of gasoline purchased ($) 30, our rule-of-thumb cutoff for invoking the Central Limit Theorem. As further evidence for normality, Figure 5.18 shows a normal probability plot of the 1000 x values; the linear pattern is very prominent. It is typically not non-normality in the central part of the population distribution that causes the CLT to fail, but instead very substantial skewness. Density 0.14 0.12 0.10 0.08 0.06 0.04 0.02 Mean 0.00 18 21 24 27 30 33 36 Figure 5.17 Approximate sampling distribution of the sample mean amount purchased when n 15 and the population distribution is as shown in Figure 5.16 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 228 CHAPTER 5 Joint Probability Distributions and Random Samples 99.99 Mean 26.49 StDev 3.112 N 1000 RJ 0.999 P-Value > 0.100 99 Percent 95 80 50 20 5 1 0.01 15 20 25 30 35 40 Mean Figure 5.18 Normal probability plot from Minitab of the 1000 x values based on samples of size n 15 ■ Other Applications of the Central Limit Theorem The CLT can be used to justify the normal approximation to the binomial distribution discussed in Chapter 4. Recall that a binomial variable X is the number of successes in a binomial experiment consisting of n independent success/failure trials with p P(S) for any particular trial. Define a new rv X1 by X1 5 e 1 0 if the 1st trial results in a success if the 1st trial results in a failure and define X2, X3, . . . , Xn analogously for the other n 1 trials. Each Xi indicates whether or not there is a success on the corresponding trial. Because the trials are independent and P(S) is constant from trial to trial, the Xi’s are iid (a random sample from a Bernoulli distribution). The CLT then implies that if n is sufficiently large, both the sum and the average of the Xi’s have approximately normal distributions. When the Xi’s are summed, a 1 is added for every S that occurs and a 0 for every F, so X1 . . . Xn X. The sample mean of the Xi’s is X/n, the sample proportion of successes. That is, both X and X/n are approximately normal when n is large. The necessary sample size for this approximation depends on the value of p: When p is close to .5, the distribution of each Xi is reasonably symmetric (see Figure 5.19), whereas the distribution is quite skewed when p is near 0 or 1. Using the approximation only if both np 10 and n(1 p) 10 ensures that n is large enough to overcome any skewness in the underlying Bernoulli distribution. 0 1 (a) 0 1 (b) Figure 5.19 Two Bernoulli distributions: (a) p .4 (reasonably symmetric); (b) p .1 (very skewed) Recall from Section 4.5 that X has a lognormal distribution if ln(X) has a normal distribution. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.4 The Distribution of the Sample Mean PROPOSITION 229 Let X1, X2, . . . , Xn be a random sample from a distribution for which only positive values are possible [P(Xi 0) 1]. Then if n is sufficiently large, the product Y X1X2 . . . Xn has approximately a lognormal distribution. To verify this, note that ln(Y) ln(X1) ln(X2) . . . ln(Xn) Since ln(Y) is a sum of independent and identically distributed rv’s [the ln(Xi)s], it is approximately normal when n is large, so Y itself has approximately a lognormal distribution. As an example of the applicability of this result, Bury (Statistical Models in Applied Science, Wiley, p. 590) argues that the damage process in plastic flow and crack propagation is a multiplicative process, so that variables such as percentage elongation and rupture strength have approximately lognormal distributions. EXERCISES Section 5.4 (46–57) 46. The inside diameter of a randomly selected piston ring is a random variable with mean value 12 cm and standard deviation .04 cm. a. If X is the sample mean diameter for a random sample of n 16 rings, where is the sampling distribution of X centered, and what is the standard deviation of the X distribution? b. Answer the questions posed in part (a) for a sample size of n 64 rings. c. For which of the two random samples, the one of part (a) or the one of part (b), is X more likely to be within .01 cm of 12 cm? Explain your reasoning. 47. Refer to Exercise 46. Suppose the distribution of diameter is normal. a. Calculate P(11.99 X 12.01) when n 16. b. How likely is it that the sample mean diameter exceeds 12.01 when n 25? 48. The National Health Statistics Reports dated Oct. 22, 2008, stated that for a sample size of 277 18-year-old American males, the sample mean waist circumference was 86.3 cm. A somewhat complicated method was used to estimate various population percentiles, resulting in the following values: 5th 69.6 10th 70.9 25th 75.2 50th 81.3 75th 95.4 90th 107.1 95th 116.4 a. Is it plausible that the waist size distribution is at least approximately normal? Explain your reasoning. If your answer is no, conjecture the shape of the population distribution. b. Suppose that the population mean waist size is 85 cm and that the population standard deviation is 15 cm. How likely is it that a random sample of 277 individuals will result in a sample mean waist size of at least 86.3 cm? c. Referring back to (b), suppose now that the population mean waist size in 82 cm. Now what is the (approximate) probability that the sample mean will be at least 86.3 cm? In light of this calculation, do you think that 82 cm is a reasonable value for m? 49. There are 40 students in an elementary statistics class. On the basis of years of experience, the instructor knows that the time needed to grade a randomly chosen first examination paper is a random variable with an expected value of 6 min and a standard deviation of 6 min. a. If grading times are independent and the instructor begins grading at 6:50 P.M. and grades continuously, what is the (approximate) probability that he is through grading before the 11:00 P.M. TV news begins? b. If the sports report begins at 11:10, what is the probability that he misses part of the report if he waits until grading is done before turning on the TV? 50. The breaking strength of a rivet has a mean value of 10,000 psi and a standard deviation of 500 psi. a. What is the probability that the sample mean breaking strength for a random sample of 40 rivets is between 9900 and 10,200? b. If the sample size had been 15 rather than 40, could the probability requested in part (a) be calculated from the given information? 51. The time taken by a randomly selected applicant for a mortgage to fill out a certain form has a normal distribution with mean value 10 min and standard deviation 2 min. If five individuals fill out a form on one day and six on another, what is the probability that the sample average amount of time taken on each day is at most 11 min? 52. The lifetime of a certain type of battery is normally distributed with mean value 10 hours and standard deviation Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 230 CHAPTER 5 Joint Probability Distributions and Random Samples 1 hour. There are four batteries in a package. What lifetime value is such that the total lifetime of all batteries in a package exceeds that value for only 5% of all packages? 53. Rockwell hardness of pins of a certain type is known to have a mean value of 50 and a standard deviation of 1.2. a. If the distribution is normal, what is the probability that the sample mean hardness for a random sample of 9 pins is at least 51? b. Without assuming population normality, what is the (approximate) probability that the sample mean hardness for a random sample of 40 pins is at least 51? 54. Suppose the sediment density (g/cm) of a randomly selected specimen from a certain region is normally distributed with mean 2.65 and standard deviation .85 (suggested in “Modeling Sediment and Water Column Interactions for Hydrophobic Pollutants,” Water Research, 1984: 1169–1174). a. If a random sample of 25 specimens is selected, what is the probability that the sample average sediment density is at most 3.00? Between 2.65 and 3.00? b. How large a sample size would be required to ensure that the first probability in part (a) is at least .99? 55. The number of parking tickets issued in a certain city on any given weekday has a Poisson distribution with parameter m 50. What is the approximate probability that a. Between 35 and 70 tickets are given out on a particular day? [Hint: When m is large, a Poisson rv has approximately a normal distribution.] b. The total number of tickets given out during a 5-day week is between 225 and 275? 56. A binary communication channel transmits a sequence of “bits” (0s and 1s). Suppose that for any particular bit transmitted, there is a 10% chance of a transmission error (a 0 becoming a 1 or a 1 becoming a 0). Assume that bit errors occur independently of one another. a. Consider transmitting 1000 bits. What is the approximate probability that at most 125 transmission errors occur? b. Suppose the same 1000-bit message is sent two different times independently of one another. What is the approximate probability that the number of errors in the first transmission is within 50 of the number of errors in the second? 57. Suppose the distribution of the time X (in hours) spent by students at a certain university on a particular project is gamma with parameters a 50 and b 2. Because a is large, it can be shown that X has approximately a normal distribution. Use this fact to compute the approximate probability that a randomly selected student spends at most 125 hours on the project. 5.5 The Distribution of a Linear Combination The sample mean X and sample total To are special cases of a type of random variable that arises very frequently in statistical applications. DEFINITION Given a collection of n random variables X1, . . . , Xn and n numerical constants a1, . . . , an, the rv n Y 5 a1X1 1 c 1 an X n 5 g ai Xi (5.7) i51 is called a linear combination of the Xi’s. For example, 4X1 5X2 8X3 is a linear combination of X1, X2, and X3 with a1 4, a2 5, and a3 8. Taking a1 a2 . . . an 1 gives Y X1 . . . Xn To, and a1 5 a2 5 c 5 an 5 1n yields Y5 1 1 1 1 X 1 c 1 Xn 5 (X1 1 c 1 Xn) 5 To 5 X n 1 n n n Notice that we are not requiring the Xi’s to be independent or identically distributed. All the Xi’s could have different distributions and therefore different mean values and variances. We first consider the expected value and variance of a linear combination. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.5 The Distribution of a Linear Combination PROPOSITION 231 Let X1, X2, . . . , Xn have mean values m1, . . . , mn, respectively, and variances s21, c, s2n, respectively. 1. Whether or not the Xi’s are independent, E(a1X1 a2X2 . . . anXn) a1E(X1) a2E(X2) . . . anE(Xn) am ...am (5.8) 1 1 n n 2. If X1, . . . , Xn are independent, V(a1X1 1 a2X2 1 c 1 anXn) 5 a 21V(X1) 1 a 22V(X2) 1 c 1 a 2nV(Xn) 5 a 21s21 1 c 1 a 2ns2n (5.9) and sa1X11c1anXn 5 1a 21s21 1 c 1 a 2ns2n (5.10) 3. For any X1, . . . , Xn, n V(a1X1 1 c 1 anXn) 5 n g g aiajCov(Xi, Xj) (5.11) i51 j51 Proofs are sketched out at the end of the section. A paraphrase of (5.8) is that the expected value of a linear combination is the same as the linear combination of the expected values—for example, E(2X1 5X2) 2m1 5m2. The result (5.9) in Statement 2 is a special case of (5.11) in Statement 3; when the Xi’s are independent, Cov(Xi, Xj) 0 for i ⬆ j and V(Xi) for i j (this simplification actually occurs when the Xi’s are uncorrelated, a weaker condition than independence). Specializing to the case of a random sample (Xi’s iid) with ai 1/n for every i gives E(X) m and V(X) s2/n, as discussed in Section 5.4. A similar comment applies to the rules for To. Example 5.29 A gas station sells three grades of gasoline: regular, extra, and super. These are priced at $3.00, $3.20, and $3.40 per gallon, respectively. Let X1, X2, and X3 denote the amounts of these grades purchased (gallons) on a particular day. Suppose the Xi’s are independent with m1 1000, m2 500, m3 300, s1 100, s2 80, and s3 50. The revenue from sales is Y 3.0X1 3.2X2 3.4X3, and E(Y) 3.0m1 3.2m2 3.4m3 $5620 V(Y) 5 (3.0)2s21 1 (3.2)2s22 1 (3.4)2s23 5 184,436 sY 5 1184,436 5 $429.46 ■ The Difference Between Two Random Variables An important special case of a linear combination results from taking n 2, a1 1, and a2 1: Y a1X1 a2X2 X1 X2 We then have the following corollary to the proposition. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 232 CHAPTER 5 Joint Probability Distributions and Random Samples COROLLARY E(X1 X2) E(X1) E(X2) for any two rv’s X1 and X2. V(X1 X2) V(X1) V(X2) if X1 and X2 are independent rv’s. The expected value of a difference is the difference of the two expected values, but the variance of a difference between two independent variables is the sum, not the difference, of the two variances. There is just as much variability in X1 X2 as in X1 X2 [writing X1 X2 X1 (1)X2, (1)X2 has the same amount of variability as X2 itself]. Example 5.30 A certain automobile manufacturer equips a particular model with either a six-cylinder engine or a four-cylinder engine. Let X1 and X2 be fuel efficiencies for independently and randomly selected six-cylinder and four-cylinder cars, respectively. With m1 22, m2 26, s1 1.2, and s2 1.5, E(X1 X2) m1 m2 22 26 4 V(X1 2 X2) 5 s21 1 s22 5 (1.2)2 1 (1.5)2 5 3.69 sX12X2 5 13.69 5 1.92 If we relabel so that X1 refers to the four-cylinder car, then E(X1 X2) 4, but the variance of the difference is still 3.69. ■ The Case of Normal Random Variables When the Xi’s form a random sample from a normal distribution, X and To are both normally distributed. Here is a more general result concerning linear combinations. PROPOSITION Example 5.31 (Example 5.29 continued) If X1, X2, . . . , Xn are independent, normally distributed rv’s (with possibly different means and/or variances), then any linear combination of the Xi’s also has a normal distribution. In particular, the difference X1 X2 between two independent, normally distributed variables is itself normally distributed. The total revenue from the sale of the three grades of gasoline on a particular day was Y 3.0X1 3.2X2 3.4X3, and we calculated mY 5620 and (assuming independence) sY 429.46. If the Xis are normally distributed, the probability that revenue exceeds 4500 is 4500 2 5620 b 429.46 5 P(Z . 22.61) 5 1 2 P(Y . 4500) 5 PaZ . (22.61) 5 .9955 ■ The CLT can also be generalized so it applies to certain linear combinations. Roughly speaking, if n is large and no individual term is likely to contribute too much to the overall value, then Y has approximately a normal distribution. Proofs for the Case n 2 For the result concerning expected values, suppose that X1 and X2 are continuous with joint pdf f(x1, x2). Then Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 5.5 The Distribution of a Linear Combination ` E(a1X1 1 a2X2) 5 233 ` 冮2` 冮2` (a1x1 1 a2x2)f(x1, x2) dx1 dx2 5 a1 冮 ` ` 冮 x1f(x1, x2) dx2 dx1 2` 2` 1 a2 冮 ` ` 冮 x2f(x1, x2) dx1 dx2 2` 2` 5 a1 冮 ` 2` x1 fX1(x1) dx1 1 a2 冮 ` 2` x2 fX2(x2) dx2 a1E(X1) a2E(X2) Summation replaces integration in the discrete case. The argument for the variance result does not require specifying whether either variable is discrete or continuous. Recalling that V(Y) E[(Y mY)2], V(a1X1 a2X2) E{[a1X1 a2X2 (a1m1 a2m2)]2} 5 E5a 21(X1 2 m1)2 1 a 22(X2 2 m2)2 1 2a1a2(X1 2 m1)(X2 2 m2)6 The expression inside the braces is a linear combination of the variables Y1 (X1 m1)2, Y2 (X2 m2)2, and Y3 (X1 m1)(X2 m2), so carrying the E operation through to the three terms gives a 21V(X1) 1 a 22V(X2) 1 2a1a2 Cov(X1, X2) as required. ■ EXERCISES Section 5.5 (58–74) 58. A shipping company handles containers in three different sizes: (1) 27 ft3 (3 3 3), (2) 125 ft3, and (3) 512 ft3. Let Xi (i 1, 2, 3) denote the number of type i containers shipped during a given week. With mi E(Xi) and s2i 5 V(Xi), suppose that the mean values and standard deviations are as follows: m1 200 s1 10 m2 250 s2 12 m3 100 s3 8 a. Assuming that X1, X2, X3 are independent, calculate the expected value and variance of the total volume shipped. [Hint: Volume 27X1 125X2 512X3.] b. Would your calculations necessarily be correct if the Xi’s were not independent? Explain. 59. Let X1, X2, and X3 represent the times necessary to perform three successive repair tasks at a certain service facility. Suppose they are independent, normal rv’s with expected values m1, m2, and m3 and variances s21, s22, and s23, respectively. a. If m m2 m3 60 and s21 5 s22 5 s23 5 15, calculate P(To 200) and P(150 To 200)? b. Using the mi’s and si’s given in part (a), calculate both P(55 X) and P(58 X 62). c. Using the mi’s and si’s given in part (a), calculate and interpret P(10 X1 .5X2 .5X3 5). d. If m1 40, m2 50, m3 60, s21 5 10, s22 5 12, and s23 5 14, calculate P(X1 X2 X3 160) and also P(X1 X2 2X3). 60. Five automobiles of the same type are to be driven on a 300mile trip. The first two will use an economy brand of gasoline, and the other three will use a name brand. Let X1, X2, X3, X4, and X5 be the observed fuel efficiencies (mpg) for the five cars. Suppose these variables are independent and normally distributed with m1 m2 20, m3 m4 m5 21, and s2 4 for the economy brand and 3.5 for the name brand. Define an rv Y by Y5 X1 1 X2 X3 1 X4 1 X5 2 2 3 so that Y is a measure of the difference in efficiency between economy gas and name-brand gas. Compute P(0 Y) and P(1 Y 1). [Hint: Y a1X1 . . . a5X5, with a1 5 1 , c, a5 5 21.] 2 3 61. Exercise 26 introduced random variables X and Y, the number of cars and buses, respectively, carried by a ferry on a single trip. The joint pmf of X and Y is given in the table in Exercise 7. It is readily verified that X and Y are independent. a. Compute the expected value, variance, and standard deviation of the total number of vehicles on a single trip. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 234 CHAPTER 5 Joint Probability Distributions and Random Samples b. If each car is charged $3 and each bus $10, compute the expected value, variance, and standard deviation of the revenue resulting from a single trip. 62. Manufacture of a certain component requires three different machining operations. Machining time for each operation has a normal distribution, and the three times are independent of one another. The mean values are 15, 30, and 20 min, respectively, and the standard deviations are 1, 2, and 1.5 min, respectively. What is the probability that it takes at most 1 hour of machining time to produce a randomly selected component? 63. Refer to Exercise 3. a. Calculate the covariance between X1 the number of customers in the express checkout and X2 the number of customers in the superexpress checkout. b. Calculate V(X1 X2). How does this compare to V(X1) V(X2)? 64. Suppose your waiting time for a bus in the morning is uniformly distributed on [0, 8], whereas waiting time in the evening is uniformly distributed on [0, 10] independent of morning waiting time. a. If you take the bus each morning and evening for a week, what is your total expected waiting time? [Hint: Define rv’s X1, . . . , X10 and use a rule of expected value.] b. What is the variance of your total waiting time? c. What are the expected value and variance of the difference between morning and evening waiting times on a given day? d. What are the expected value and variance of the difference between total morning waiting time and total evening waiting time for a particular week? 65. Suppose that when the pH of a certain chemical compound is 5.00, the pH measured by a randomly selected beginning chemistry student is a random variable with mean 5.00 and standard deviation .2. A large batch of the compound is subdivided and a sample given to each student in a morning lab and each student in an afternoon lab. Let X the average pH as determined by the morning students and Y the average pH as determined by the afternoon students. a. If pH is a normal variable and there are 25 students in each lab, compute P(.1 X Y .1). [Hint: X Y is a linear combination of normal variables, so is normally distributed. Compute mX2Y and sX2Y.] b. If there are 36 students in each lab, but pH determinations are not assumed normal, calculate (approximately) P(.1 X Y .1). 66. If two loads are applied to a cantilever beam as shown in the accompanying drawing, the bending moment at 0 due to the loads is a1X1 a2X2. y (0, 1) (x, 1 x) a. Suppose that X1 and X2 are independent rv’s with means 2 and 4 kips, respectively, and standard deviations .5 and 1.0 kip, respectively. If a1 5 ft and a2 10 ft, what is the expected bending moment and what is the standard deviation of the bending moment? b. If X1 and X2 are normally distributed, what is the probability that the bending moment will exceed 75 kip-ft? c. Suppose the positions of the two loads are random variables. Denoting them by A1 and A2, assume that these variables have means of 5 and 10 ft, respectively, that each has a standard deviation of .5, and that all Ai’s and Xi’s are independent of one another. What is the expected moment now? d. For the situation of part (c), what is the variance of the bending moment? e. If the situation is as described in part (a) except that Corr(X1, X2) .5 (so that the two loads are not independent), what is the variance of the bending moment? 67. One piece of PVC pipe is to be inserted inside another piece. The length of the first piece is normally distributed with mean value 20 in. and standard deviation .5 in. The length of the second piece is a normal rv with mean and standard deviation 15 in. and .4 in., respectively. The amount of overlap is normally distributed with mean value 1 in. and standard deviation .1 in. Assuming that the lengths and amount of overlap are independent of one another, what is the probability that the total length after insertion is between 34.5 in. and 35 in.? 68. Two airplanes are flying in the same direction in adjacent parallel corridors. At time t 0, the first airplane is 10 km ahead of the second one. Suppose the speed of the first plane (km/hr) is normally distributed with mean 520 and standard deviation 10 and the second plane’s speed is also normally distributed with mean and standard deviation 500 and 10, respectively. a. What is the probability that after 2 hr of flying, the second plane has not caught up to the first plane? b. Determine the probability that the planes are separated by at most 10 km after 2 hr. 69. Three different roads feed into a particular freeway entrance. Suppose that during a fixed time period, the number of cars coming from each road onto the freeway is a random variable, with expected value and standard deviation as given in the table. Road 1 Road 2 Road 3 Expected value Standard deviation 800 16 1000 25 600 18 a. What is the expected total number of cars entering the freeway at this point during the period? [Hint: Let Xi the number from road i.] b. What is the variance of the total number of entering cars? Have you made any assumptions about the relationship between the numbers of cars on the different roads? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Supplementary Exercises c. With Xi denoting the number of cars entering from road i during the period, suppose that Cov(X1, X2) 80, Cov(X1, X3) 90, and Cov(X2, X3) 100 (so that the three streams of traffic are not independent). Compute the expected total number of entering cars and the standard deviation of the total. 70. Consider a random sample of size n from a continuous distribution having median 0 so that the probability of any one observation being positive is .5. Disregarding the signs of the observations, rank them from smallest to largest in absolute value, and let W the sum of the ranks of the observations having positive signs. For example, if the observations are .3, .7, 2.1, and 2.5, then the ranks of positive observations are 2 and 3, so W 5. In Chapter 15, W will be called Wilcoxon’s signed-rank statistic. W can be represented as follows: W 1 Y1 2 Y2 3 Y3 . . . n Yn n 5 g i # Yi i51 where the Yi’s are independent Bernoulli rv’s, each with p .5 (Yi 1 corresponds to the observation with rank i being positive). a. Determine E(Yi) and then E(W) using the equation for W. [Hint: The first n positive integers sum to n(n 1)/2.] b. Determine V(Yi) and then V(W). [Hint: The sum of the squares of the first n positive integers can be expressed as n(n 1)(2n 1)/6.] 71. In Exercise 66, the weight of the beam itself contributes to the bending moment. Assume that the beam is of uniform thickness and density so that the resulting load is uniformly distributed on the beam. If the weight of the beam is random, the resulting load from the weight is also random; denote this load by W (kip-ft). a. If the beam is 12 ft long, W has mean 1.5 and standard deviation .25, and the fixed loads are as described in part (a) of Exercise 66, what are the expected value and variance of the bending moment? [Hint: If the load due to the SUPPLEMENTARY EXERCISES x 12 15 20 beam were w kip-ft, the contribution to the bending 12 moment would be w冕0 x dx.] b. If all three variables (X1, X2, and W) are normally distributed, what is the probability that the bending moment will be at most 200 kip-ft? 72. I have three errands to take care of in the Administration Building. Let Xi the time that it takes for the ith errand (i 1, 2, 3), and let X4 the total time in minutes that I spend walking to and from the building and between each errand. Suppose the Xi’s are independent, and normally distributed, with the following means and standard deviations: m1 15, s1 4, m2 5, s2 1, m3 8, s3 2, m4 12, s4 3. I plan to leave my office at precisely 10:00 A.M. and wish to post a note on my door that reads, “I will return by t A.M.” What time t should I write down if I want the probability of my arriving after t to be .01? 73. Suppose the expected tensile strength of type-A steel is 105 ksi and the standard deviation of tensile strength is 8 ksi. For type-B steel, suppose the expected tensile strength and standard deviation of tensile strength are 100 ksi and 6 ksi, respectively. Let X the sample average tensile strength of a random sample of 40 type-A specimens, and let Y the sample average tensile strength of a random sample of 35 type-B specimens. a. What is the approximate distribution of X? Of Y? b. What is the approximate distribution of X Y? Justify your answer. c. Calculate (approximately) P(1 X Y 1). d. Calculate P(X Y 10). If you actually observed X Y 10, would you doubt that m1 m2 5? 74. In an area having sandy soil, 50 small trees of a certain type were planted, and another 50 trees were planted in an area having clay soil. Let X the number of trees planted in sandy soil that survive 1 year and Y the number of trees planted in clay soil that survive 1 year. If the probability that a tree planted in sandy soil will survive 1 year is .7 and the probability of 1-year survival in clay soil is .6, compute an approximation to P(5 X Y 5) (do not bother with the continuity correction). (75–96) 75. A restaurant serves three fixed-price dinners costing $12, $15, and $20. For a randomly selected couple dining at this restaurant, let X the cost of the man’s dinner and Y the cost of the woman’s dinner. The joint pmf of X and Y is given in the following table: y p(x, y) 235 12 15 20 .05 .05 0 .05 .10 .20 .10 .35 .10 a. Compute the marginal pmf’s of X and Y. b. What is the probability that the man’s and the woman’s dinner cost at most $15 each? c. Are X and Y independent? Justify your answer. d. What is the expected total cost of the dinner for the two people? e. Suppose that when a couple opens fortune cookies at the conclusion of the meal, they find the message “You will receive as a refund the difference between the cost of the more expensive and the less expensive meal that you have chosen.” How much would the restaurant expect to refund? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 236 CHAPTER 5 Joint Probability Distributions and Random Samples 76. In cost estimation, the total cost of a project is the sum of component task costs. Each of these costs is a random variable with a probability distribution. It is customary to obtain information about the total cost distribution by adding together characteristics of the individual component cost distributions—this is called the “roll-up” procedure. For example, E(X1 . . . Xn) E(X1) . . . E(Xn), so the roll-up procedure is valid for mean cost. Suppose that there are two component tasks and that X1 and X2 are independent, normally distributed random variables. Is the roll-up procedure valid for the 75th percentile? That is, is the 75th percentile of the distribution of X1 X2 the same as the sum of the 75th percentiles of the two individual distributions? If not, what is the relationship between the percentile of the sum and the sum of percentiles? For what percentiles is the roll-up procedure valid in this case? 77. A health-food store stocks two different brands of a certain type of grain. Let X the amount (lb) of brand A on hand and Y the amount of brand B on hand. Suppose the joint pdf of X and Y is f(x, y) 5 e kxy 0 x $ 0, y $ 0, 20 # x 1 y # 30 otherwise a. Draw the region of positive density and determine the value of k. b. Are X and Y independent? Answer by first deriving the marginal pdf of each variable. c. Compute P(X Y 25). d. What is the expected total amount of this grain on hand? e. Compute Cov(X, Y) and Corr(X, Y). f. What is the variance of the total amount of grain on hand? 78. The article “Stochastic Modeling for Pavement Warranty Cost Estimation” (J. of Constr. Engr. and Mgmnt., 2009: 352–359) proposes the following model for the distribution of Y time to pavement failure. Let X1 be the time to failure due to rutting, and X2 be the time to failure due to transverse cracking; these two rvs are assumed independent. Then Y min(X1, X2). The probability of failure due to either one of these distress modes is assumed to be an increasing function of time t. After making certain distributional assumptions, the following form of the cdf for each mode is obtained: c (a 1 bt) >(c 1 dt 1 et2)1/2 d random with expected value 900 and standard deviation 100, and calorie intake at dinner is a random variable with expected value 2000 and standard deviation 180. Assuming that intakes at different meals are independent of one another, what is the probability that average calorie intake per day over the next (365-day) year is at most 3500? [Hint: Let Xi, Yi, and Zi denote the three calorie intakes on day i. Then total intake is given by (Xi Yi Zi).] 80. The mean weight of luggage checked by a randomly selected tourist-class passenger flying between two cities on a certain airline is 40 lb, and the standard deviation is 10 lb. The mean and standard deviation for a business-class passenger are 30 lb and 6 lb, respectively. a. If there are 12 business-class passengers and 50 tourist-class passengers on a particular flight, what are the expected value of total luggage weight and the standard deviation of total luggage weight? b. If individual luggage weights are independent, normally distributed rv’s, what is the probability that total luggage weight is at most 2500 lb? 81. We have seen that if E(X1) E(X2) . . . E(Xn) m, then E(X 1 . . . X n ) nm. In some applications, the number of X i ’s under consideration is not a fixed number n but instead is an rv N. For example, let N the number of components that are brought into a repair shop on a particular day, and let X i denote the repair shop time for the ith component. Then the total repair time is X 1 X 2 . . . X N , the sum of a random number of random variables. When N is independent of the X i ’s, it can be shown that E(X1 . . . XN) E(N) m a. If the expected number of components brought in on a particularly day is 10 and expected repair time for a randomly submitted component is 40 min, what is the expected total repair time for components submitted on any particular day? b. Suppose components of a certain type come in for repair according to a Poisson process with a rate of 5 per hour. The expected number of defects per component is 3.5. What is the expected value of the total number of defects on components submitted for repair during a 4-hour period? Be sure to indicate how your answer follows from the general result just given. where is the standard normal cdf. Values of the five parameters a, b, c, d, and e are 25.49, 1.15, 4.45, 1.78, and .171 for cracking and 21.27, .0325, .972, .00028, and .00022 for rutting. Determine the probability of pavement failure within t 5 years and also t 10 years. 82. Suppose the proportion of rural voters in a certain state who favor a particular gubernatorial candidate is .45 and the proportion of suburban and urban voters favoring the candidate is .60. If a sample of 200 rural voters and 300 urban and suburban voters is obtained, what is the approximate probability that at least 250 of these voters favor this candidate? 79. Suppose that for a certain individual, calorie intake at breakfast is a random variable with expected value 500 and standard deviation 50, calorie intake at lunch is 83. Let m denote the true pH of a chemical compound. A sequence of n independent sample pH determinations will be made. Suppose each sample pH is a random variable Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Supplementary Exercises with expected value m and standard deviation .1. How many determinations are required if we wish the probability that the sample average is within .02 of the true pH to be at least .95? What theorem justifies your probability calculation? 84. If the amount of soft drink that I consume on any given day is independent of consumption on any other day and is normally distributed with m 13 oz and s 2 and if I currently have two six-packs of 16-oz bottles, what is the probability that I still have some soft drink left at the end of 2 weeks (14 days)? 85. Refer to Exercise 58, and suppose that the Xi’s are independent with each one having a normal distribution. What is the probability that the total volume shipped is at most 100,000 ft3? 86. A student has a class that is supposed to end at 9:00 A.M. and another that is supposed to begin at 9:10 A.M. Suppose the actual ending time of the 9 A.M. class is a normally distributed rv X1 with mean 9:02 and standard deviation 1.5 min and that the starting time of the next class is also a normally distributed rv X2 with mean 9:10 and standard deviation 1 min. Suppose also that the time necessary to get from one classroom to the other is a normally distributed rv X3 with mean 6 min and standard deviation 1 min. What is the probability that the student makes it to the second class before the lecture starts? (Assume independence of X1, X2, and X3, which is reasonable if the student pays no attention to the finishing time of the first class.) 87. a. Use the general formula for the variance of a linear combination to write an expression for V(aX Y). Then let a sY /sX, and show that r 1. [Hint: Variance is always 0, and Cov(X, Y ) sX sY r.] b. By considering V(aX Y ), conclude that r 1. c. Use the fact that V(W) 0 only if W is a constant to show that r 1 only if Y aX b. 88. Suppose a randomly chosen individual’s verbal score X and quantitative score Y on a nationally administered aptitude examination have a joint pdf 2 (2x 1 3y) f(x, y) 5 • 5 0 0 # x # 1, 0 # y # 1 otherwise You are asked to provide a prediction t of the individual’s total score X Y. The error of prediction is the mean squared error E[(X Y t)2]. What value of t minimizes the error of prediction? 89. a. Let X1 have a chi-squared distribution with parameter n1 (see Section 4.4), and let X2 be independent of X1 and have a chi-squared distribution with parameter n2. Use the technique of Example 5.21 to show that X1 X2 has a chi-squared distribution with parameter n1 n2. 237 b. In Exercise 71 of Chapter 4, you were asked to show that if Z is a standard normal rv, then Z 2 has a chi-squared distribution with n 1. Let Z 1, Z 2, . . . , Zn be n independent standard normal rv’s. What is the distribution of Z12 1 c 1 Z 2n? Justify your answer. c. Let X1, . . . , Xn be a random sample from a normal distribution with mean m and variance s2. What is the distribution of the sum Y 5 g ni51 [(Xi 2 m)/s]2? Justify your answer. 90. a. Show that Cov(X, Y Z) Cov(X, Y) Cov(X, Z). b. Let X1 and X2 be quantitative and verbal scores on one aptitude exam, and let Y1 and Y2 be corresponding scores on another exam. If Cov(X1, Y1) 5, Cov(X1, Y2) 1, Cov(X2, Y1) 2, and Cov(X2, Y2) 8, what is the covariance between the two total scores X1 X2 and Y1 Y2? 91. A rock specimen from a particular area is randomly selected and weighed two different times. Let W denote the actual weight and X1 and X2 the two measured weights. Then X1 W E1 and X2 W E2, where E1 and E2 are the two measurement errors. Suppose that the Eis are independent of one another and of W and that V(E1) 5 V(E2) 5 s2E. a. Express r, the correlation coefficient between the two measured weights X1 and X2, in terms of s2W, the variance of actual weight, and s2X, the variance of measured weight. b. Compute r when sW 1 kg and sE .01 kg. 92. Let A denote the percentage of one constituent in a randomly selected rock specimen, and let B denote the percentage of a second constituent in that same specimen. Suppose D and E are measurement errors in determining the values of A and B so that measured values are X A D and Y B E, respectively. Assume that measurement errors are independent of one another and of actual values. a. Show that Corr(X, Y) 5 Corr(A, B) # 1Corr(X1, X2) # 1Corr(Y1, Y2) where X1 and X2 are replicate measurements on the value of A, and Y1 and Y2 are defined analogously with respect to B. What effect does the presence of measurement error have on the correlation? b. What is the maximum value of Corr(X, Y) when Corr(X1, X2) .8100 and Corr(Y1, Y2) .9025? Is this disturbing? 93. Let X1, . . . , Xn be independent rv’s with mean values m1, . . . , mn and variances s21, c, s2n. Consider a function h(x1, . . . , xn), and use it to define a new rv Y h(X1, . . . , Xn). Under rather general conditions on the h function, if the si’s are all small relative to the corresponding mi’s, it can be shown that E(Y) ⬇ h(m1, . . . , mn) and V(Y) < a 'h 2 # 2 c 'h 2 # 2 b s1 1 1 a b sn 'x1 'xn where each partial derivative is evaluated at (x1, . . . , xn) (m1, . . . , mn). Suppose three resistors with resistances X1, X2, X3 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 238 CHAPTER 5 Joint Probability Distributions and Random Samples are connected in parallel across a battery with voltage X4. Then by Ohm’s law, the current is Y 5 X4 c 1 1 1 1 1 d X1 X2 X3 Let m1 10 ohms, s1 1.0 ohm, m2 15 ohms, s2 1.0 ohm, m3 20 ohms, s3 1.5 ohms, m4 120 V, s4 4.0 V. Calculate the approximate expected value and standard deviation of the current (suggested by “Random Samplings,” CHEMTECH, 1984: 696–697). 94. A more accurate approximation to E[h(X1, . . . , Xn)] in Exercise 93 is h(m1, c,mn) 1 1 2 '2h 1 '2h s1 a 2 b 1 c 1 s2n a 2 b 2 'x 1 2 'x n Compute this for Y h(X1, X2, X3, X4) given in Exercise 93, and compare it to the leading term h(m1, . . . , mn). 95. Let X and Y be independent standard normal random variables, and define a new rv by U .6X .8Y. a. Determine Corr(X, U). b. How would you alter U to obtain Corr(X, U) r for a specified value of r? 96. Let X1, X2, . . . , Xn be random variables denoting n independent bids for an item that is for sale. Suppose each Xi is uniformly distributed on the interval [100, 200]. If the seller sells to the highest bidder, how much can he expect to earn on the sale? [Hint: Let Y max(X1, X2, . . . , Xn). First find FY(y) by noting that Y y iff each Xi is y. Then obtain the pdf and E(Y).] Bibliography Devore, Jay, and Kenneth Berk, Modern Mathematical Statistics with Applications, Thomson-Brooks/Cole, Belmont, CA, 2007. A bit more sophisticated exposition of probability topics than in the present book. Olkin, Ingram, Cyrus Derman, and Leon Gleser, Probability Models and Applications (2nd ed.), Macmillan, New York, 1994. Contains a careful and comprehensive exposition of joint distributions, rules of expectation, and limit theorems. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6 Point Estimation INTRODUCTION Given a parameter of interest, such as a population mean m or population proportion p, the objective of point estimation is to use a sample to compute a number that represents in some sense a good guess for the true value of the parameter. The resulting number is called a point estimate. In Section 6.1, we present some general concepts of point estimation. In Section 6.2, we describe and illustrate two important methods for obtaining point estimates: the method of moments and the method of maximum likelihood. 239 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 240 CHAPTER 6 Point Estimation 6.1 Some General Concepts of Point Estimation Statistical inference is almost always directed toward drawing some type of conclusion about one or more parameters (population characteristics). To do so requires that an investigator obtain sample data from each of the populations under study. Conclusions can then be based on the computed values of various sample quantities. For example, let m (a parameter) denote the true average breaking strength of wire connections used in bonding semiconductor wafers. A random sample of n ⫽ 10 connections might be made, and the breaking strength of each one determined, resulting in observed strengths x1, x2, . . . , x10. The sample mean breaking strength x could then be used to draw a conclusion about the value of m. Similarly, if s 2 is the variance of the breaking strength distribution (population variance, another parameter), the value of the sample variance s 2 can be used to infer something about s 2. When discussing general concepts and methods of inference, it is convenient to have a generic symbol for the parameter of interest. We will use the Greek letter u for this purpose. The objective of point estimation is to select a single number, based on sample data, that represents a sensible value for u. Suppose, for example, that the parameter of interest is m, the true average lifetime of batteries of a certain type. A random sample of n ⫽ 3 batteries might yield observed lifetimes (hours) x1 ⫽ 5.0, x2 ⫽ 6.4, x3 ⫽ 5.9. The computed value of the sample mean lifetime is x ⫽ 5.77, and it is reasonable to regard 5.77 as a very plausible value of m—our “best guess” for the value of m based on the available sample information. Suppose we want to estimate a parameter of a single population (e.g., m or s) based on a random sample of size n. Recall from the previous chapter that before data is available, the sample observations must be considered random variables (rv’s) X1, X2, . . . , Xn. It follows that any function of the Xi ’s—that is, any statistic—such as the sample mean X or sample standard deviation S is also a random variable. The same is true if available data consists of more than one sample. For example, we can represent tensile strengths of m type 1 specimens and n type 2 specimens by X1, . . . , Xm and Y1, . . . , Yn, respectively. The difference between the two sample mean strengths is X ⫺ Y, the natural statistic for making inferences about m1 ⫺ m2, the difference between the population mean strengths. DEFINITION A point estimate of a parameter u is a single number that can be regarded as a sensible value for u. A point estimate is obtained by selecting a suitable statistic and computing its value from the given sample data. The selected statistic is called the point estimator of u. In the battery example just given, the estimator used to obtain the point estimate of m was X, and the point estimate of m was 5.77. If the three observed lifetimes had instead been x1 ⫽ 5.6, x2 ⫽ 4.5, and x3 ⫽ 6.1, use of the estimator X would have resulted in the estimate x ⫽ (5.6 ⫹ 4.5 ⫹ 6.1)/3 ⫽ 5.40. The symbol û (“theta hat”) is customarily used to denote both the estimator of u and the point estimate resulting from a given sample.* Thus m̂ 5 X is read as “the point estimator of m is the sample ˆ (an uppercase theta) for the estimator, but this is cumber* Following earlier notation, we could use ⌰ some to write. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6.1 Some General Concepts of Point Estimation 241 mean X.” The statement “the point estimate of m is 5.77” can be written concisely as m̂ 5 5.77. Notice that in writing û 5 72.5, there is no indication of how this point estimate was obtained (what statistic was used). It is recommended that both the estimator and the resulting estimate be reported. Example 6.1 An automobile manufacturer has developed a new type of bumper, which is supposed to absorb impacts with less damage than previous bumpers. The manufacturer has used this bumper in a sequence of 25 controlled crashes against a wall, each at 10 mph, using one of its compact car models. Let X ⫽ the number of crashes that result in no visible damage to the automobile. The parameter to be estimated is p ⫽ the proportion of all such crashes that result in no damage [alternatively, p ⫽ P(no damage in a single crash)]. If X is observed to be x ⫽ 15, the most reasonable estimator and estimate are estimator p̂ 5 X n estimate 5 x 15 5 5 .60 n 25 ■ If for each parameter of interest there were only one reasonable point estimator, there would not be much to point estimation. In most problems, though, there will be more than one reasonable estimator. Example 6.2 Reconsider the accompanying 20 observations on dielectric breakdown voltage for pieces of epoxy resin first introduced in Example 4.30 (Section 4.6). 24.46 25.61 26.25 26.42 26.66 27.15 27.31 27.54 27.74 27.94 27.98 28.04 28.28 28.49 28.50 28.87 29.11 29.13 29.50 30.88 The pattern in the normal probability plot given there is quite straight, so we now assume that the distribution of breakdown voltage is normal with mean value m. Because normal distributions are symmetric, m is also the median lifetime of the distribution. The given observations are then assumed to be the result of a random sample X1, X2, . . . , X20 from this normal distribution. Consider the following estimators and resulting estimates for m: a. Estimator ⫽ X, estimate ⫽ x ⫽ ⌺xi /n ⫽ 555.86/20 ⫽ 27.793 | x ⫽ (27.94 ⫹ 27.98)/2 ⫽ 27.960 b. Estimator ⫽ X, estimate ⫽ | c. Estimator ⫽ [min(Xi) ⫹ max(Xi)]/2 ⫽ the average of the two extreme lifetimes, estimate ⫽ [min(xi) ⫹ max(xi)]/2 ⫽ (24.46 ⫹ 30.88)/2 ⫽ 27.670 d. Estimator ⫽ Xtr(10), the 10% trimmed mean (discard the smallest and largest 10% of the sample and then average), estimate ⫽ x tr(10) 555.86 2 24.46 2 25.61 2 29.50 2 30.88 5 16 ⫽ 27.838 Each one of the estimators (a)–(d) uses a different measure of the center of the sample to estimate m. Which of the estimates is closest to the true value? We cannot answer this without knowing the true value. A question that can be answered is, “Which estimator, when used on other samples of Xi’s, will tend to produce estimates closest to the true value?” We will shortly consider this type of question. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 242 CHAPTER 6 Point Estimation Example 6.3 The article “Is a Normal Distribution the Most Appropriate Statistical Distribution for Volumetric Properties in Asphalt Mixtures?” first cited in Example 4.26, reported the following observations on X ⫽ voids filled with asphalt (%) for 52 specimens of a certain type of hot-mix asphalt: 74.33 74.69 68.83 64.93 79.87 79.97 71.07 77.25 75.09 67.33 81.96 75.09 73.82 74.84 62.54 66.08 79.51 74.38 77.42 60.90 67.47 67.31 84.12 77.67 79.35 60.75 72.00 74.87 80.61 83.73 82.27 74.09 66.51 69.40 79.89 80.39 77.75 65.36 68.21 70.83 79.70 76.90 78.65 67.84 64.46 81.73 78.74 77.19 69.97 64.34 82.50 77.28 Let’s estimate the variance s 2 of the population distribution. A natural estimator is the sample variance: 2 g(X i 2 X ) 2 2 2 ŝ 5 S 5 n21 Minitab gave the following output from a request to display descriptive statistics: Variable VFA(B) Count 52 Mean 73.880 SE Mean 0.889 StDev 6.413 Variance 41.126 Q1 67.933 Median 74.855 Q3 79.470 Thus the point estimate of the population variance is ŝ2 5 s 2 5 g(xi 2 x ) 2 5 41.126 52 2 1 [alternatively, the computational formula for the numerator of s2 gives Sxx 5 g xi2 2 (gxi)2 / n 5 285,929.5964 2 (3841.78) 2 / 52 5 2097.4124]. A point estimate of the population standard deviation is then ŝ 5 s 5141.126 5 6.413. An alternative estimator results from using the divisor n rather than n ⫺ 1: 22 g(Xi 2X ) 2097.4124 2 ŝ 5 , estimate 5 5 40.335 n 52 We will shortly indicate why many statisticians prefer S 2 to this latter estimator. The cited article considered fitting four different distributions to the data: normal, lognormal, two-parameter Weibull, and three-parameter Weibull. Several different techniques were used to conclude that the two-parameter Weibull provided the best fit (a normal probability plot of the data shows some deviation from a linear pattern). From Section 4.5, the variance of a Weibull random variable is s2 5 b2 5⌫(1 1 2/a) 2 [⌫(1 1 1/a)]26 where a and b are the shape and scale parameters of the distribution. The authors of the article used the method of maximum likelihood (see Section 6.2) to estimate these parameters. The resulting estimates were â 5 11.9731, b̂ 5 77.0153. A sensible estimate of the population variance can now be obtained from substituting the estimates of the two parameters into the expression for s2; the result is ŝ2 5 56.035. This latter estimate is obviously quite different from the sample variance. Its validity depends on the population distribution being Weibull, whereas the sample variance is a sensible way to estimate s2 when there is uncertainty as to the specific form of the population distribution. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6.1 Some General Concepts of Point Estimation 243 In the best of all possible worlds, we could find an estimator û for which û 5 u always. However, û is a function of the sample Xi ’s, so it is a random variable. For some samples, û will yield a value larger than u, whereas for other samples û will underestimate u. If we write û 5 u 1 error of estimation then an accurate estimator would be one resulting in small estimation errors, so that estimated values will be near the true value. A sensible way to quantify the idea of û being close to u is to consider the squared error (û 2 u)2. For some samples, û will be quite close to u and the resulting squared error will be near 0. Other samples may give values of û far from u, corresponding to very large squared errors. An omnibus measure of accuracy is the expected or mean square error MSE 5 E[(û 2 u)2]. If a first estimator has smaller MSE than does a second, it is natural to say that the first estimator is the better one. However, MSE will generally depend on the value of u. What often happens is that one estimator will have a smaller MSE for some values of u and a larger MSE for other values. Finding an estimator with the smallest MSE is typically not possible. One way out of this dilemma is to restrict attention just to estimators that have some specified desirable property and then find the best estimator in this restricted group. A popular property of this sort in the statistical community is unbiasedness. Unbiased Estimators Suppose we have two measuring instruments; one instrument has been accurately calibrated, but the other systematically gives readings smaller than the true value being measured. When each instrument is used repeatedly on the same object, because of measurement error, the observed measurements will not be identical. However, the measurements produced by the first instrument will be distributed about the true value in such a way that on average this instrument measures what it purports to measure, so it is called an unbiased instrument. The second instrument yields observations that have a systematic error component or bias. DEFINITION A point estimator û is said to be an unbiased estimator of u if E(û) 5 u for every possible value of u. If û is not unbiased, the difference E(û) 2 u is called the bias of û. That is, û is unbiased if its probability (i.e., sampling) distribution is always “centered” at the true value of the parameter. Suppose û is an unbiased estimator; then if u ⫽ 100, the û sampling distribution is centered at 100; if u ⫽ 27.5, then the ␪ˆ sampling distribution is centered at 27.5, and so on. Figure 6.1 pictures the distributions of several biased and unbiased estimators. Note that “centered” here means that the expected value, not the median, of the distribution of ␪ˆ is equal to u. pdf of ␪ˆ2 pdf of ␪ˆ2 pdf of ␪ˆ1 pdf of ␪ˆ1 ␪ Bias of ␪ˆ1 Figure 6.1 ␪ Bias of ␪ˆ1 The pdf’s of a biased estimator û1 and an unbiased estimator û2 for a parameter u Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 244 CHAPTER 6 Point Estimation It may seem as though it is necessary to know the value of u (in which case estimation is unnecessary) to see whether û is unbiased. This is not usually the case, though, because unbiasedness is a general property of the estimator’s sampling distribution—where it is centered—which is typically not dependent on any particular parameter value. In Example 6.1, the sample proportion X/n was used as an estimator of p, where X, the number of sample successes, had a binomial distribution with parameters n and p. Thus X 1 1 E( p̂ ) 5 E a b 5 E(X) 5 (np) 5 p n n n PROPOSITION When X is a binomial rv with parameters n and p, the sample proportion p̂ ⫽ X/n is an unbiased estimator of p. No matter what the true value of p is, the distribution of the estimator p̂ will be centered at the true value. Example 6.4 Suppose that X, the reaction time to a certain stimulus, has a uniform distribution on the interval from 0 to an unknown upper limit u (so the density function of X is rectangular in shape with height 1/u for 0 ⱕ x ⱕ u). It is desired to estimate u on the basis of a random sample X1, X2, . . . , Xn of reaction times. Since u is the largest possible time in the entire population of reaction times, consider as a first estimator the largest sample reaction time: û1 5 max (X1 , c, Xn). If n ⫽ 5 and x1 ⫽ 4.2, x2 ⫽ 1.7, x3 ⫽ 2.4, x4 ⫽ 3.9, and x5 ⫽ 1.3, the point estimate of u is û1 5 max(4.2, 1.7, 2.4, 3.9, 1.3) 5 4.2. Unbiasedness implies that some samples will yield estimates that exceed u and other samples will yield estimates smaller than u—otherwise u could not possibly be the center (balance point) of û1’s distribution. However, our proposed estimator will never overestimate u (the largest sample value cannot exceed the largest population value) and will underestimate u unless the largest sample value equals u. This intuitive argument shows that û1 is a biased estimator. More precisely, it can be shown (see Exercise 32) that E(û1 ) 5 n n11 # u ,u asince n , 1b n11 The bias of û1 is given by nu/(n ⫹ 1) ⫺ u ⫽ ⫺u/(n ⫹ 1), which approaches 0 as n gets large. It is easy to modify û1 to obtain an unbiased estimator of u. Consider the estimator û2 5 n11 n # max ( X1 , c, Xn ) Using this estimator on the data gives the estimate (6/5)(4.2) ⫽ 5.04. The fact that (n ⫹ 1)/n ⬎ 1 implies that û2 will overestimate u for some samples and underestimate it for others. The mean value of this estimator is Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6.1 Some General Concepts of Point Estimation E(û2) 5 E c n11 n11 max(X1 , . . . , X n)d 5 n n n11# n 5 u5u n n11 245 # E [max(X1 , . . . , X n)] If û2 is used repeatedly on different samples to estimate u, some estimates will be too large and others will be too small, but in the long run there will be no systematic tendency to underestimate or overestimate u. ■ Principle of Unbiased Estimation When choosing among several different estimators of u, select one that is unbiased. According to this principle, the unbiased estimator û2 in Example 6.4 should be preferred to the biased estimator û1. Consider now the problem of estimating s 2. PROPOSITION Let X1, X2, . . . , Xn be a random sample from a distribution with mean m and variance s2. Then the estimator 2 g (X i 2 X )2 ŝ 5 S 5 n21 2 2 is unbiased for estimating s 2. Proof For any rv Y, V(Y) ⫽ E(Y 2) ⫺ [E(Y)]2, so E(Y 2) ⫽ V(Y) ⫹ [E(Y)]2. Applying this to (gXi)2 1 d S2 5 c g X 2i 2 n n21 gives 1 1 E(S 2) 5 e gE(X i2) 2 E[(gXi) 2] f n n21 1 1 e g(s2 1 m2) 2 5V(gXi) 1 [E(gXi)]26 f n n21 1 1 1 5 e ns2 1 nm2 2 ns2 2 (nm) 2 f n n n21 5 5 1 5ns2 2 s26 5 s2 n21 (as desired) ■ The estimator that uses divisor n can be expressed as (n ⫺ 1)S 2/n, so Ec (n 2 1)S 2 n21 n21 2 d 5 E(S 2) 5 s n n n This estimator is therefore not unbiased. The bias is (n ⫺ 1)s2/n ⫺ s2 ⫽ ⫺s2/n. Because the bias is negative, the estimator with divisor n tends to underestimate s2, and this is why the divisor n ⫺ 1 is preferred by many statisticians (though when n is large, the bias is small and there is little difference between the two). Unfortunately, the fact that S 2 is unbiased for estimating s2 does not imply that S is unbiased for estimating s. Taking the square root messes up the property of Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 246 CHAPTER 6 Point Estimation unbiasedness (the expected value of the square root is not the square root of the expected value). Fortunately, the bias of S is small unless n is quite small. There are other good reasons to use S as an estimator, especially when the population distribution is normal. These will become more apparent when we discuss confidence intervals and hypothesis testing in the next several chapters. In Example 6.2, we proposed several different estimators for the mean m of a normal distribution. If there were a unique unbiased estimator for m, the estimation problem would be resolved by using that estimator. Unfortunately, this is not the case. PROPOSITION If X1, X2, . . . , Xn is a random sample from a distribution with mean m, then X is an unbiased estimator of m. If in addition the distribution is continuous and | symmetric, then X and any trimmed mean are also unbiased estimators of m. The fact that X is unbiased is just a restatement of one of our rules of expected value: E( X ) ⫽ m for every possible value of m (for discrete as well as continuous distributions). The unbiasedness of the other estimators is more difficult to verify. The next example introduces another situation in which there are several unbiased estimators for a particular parameter. Example 6.5 Under certain circumstances organic contaminants adhere readily to wafer surfaces and cause deterioration in semiconductor manufacturing devices. The paper “Ceramic Chemical Filter for Removal of Organic Contaminants” (J. of the Institute of Environmental Sciences and Technology, 2003: 59–65) discussed a recently developed alternative to conventional charcoal filters for removing organic airborne molecular contamination in cleanroom applications. One aspect of the investigation of filter performance involved studying how contaminant concentration in air related to concentration on a wafer surface after prolonged exposure. Consider the following representative data on x ⫽ DBP concentration in air and y ⫽ DBP concentration on a wafer surface after 4-hour exposure (both in mg/m3, where DBP ⫽ dibutyl phthalate). Obs. i: x: y: 1 .8 .6 2 1.3 1.1 3 1.5 4.5 4 3.0 3.5 5 11.6 14.4 6 26.6 29.1 The authors comment that “DBP adhesion on the wafer surface was roughly proportional to the DBP concentration in air.” Figure 6.2 shows a plot of y versus x—i.e., of the (x, y) pairs. Wafer DBP 30 25 20 15 10 5 0 Air DBP 0 Figure 6.2 5 10 15 20 25 30 Plot of the DBP data from Example 6.5 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6.1 Some General Concepts of Point Estimation 247 If y were exactly proportional to x, we would have y ⫽ bx for some value b, which says that the (x, y) points in the plot would lie exactly on a straight line with slope b passing through (0, 0). But this is only approximately the case. So we now assume that for any fixed x, wafer DBP is a random variable Y having mean value bx. That is, we postulate that the mean value of Y is related to x by a line passing through (0, 0) but that the observed value of Y will typically deviate from this line (this is referred to in the statistical literature as “regression through the origin”). We now wish to estimate the slope parameter b. Consider the following three estimators: [1: b̂ 5 1 Yi g n xi [2: b̂ 5 gYi gxi [3: b̂ 5 gxiYi gx 2i The resulting estimates based on the given data are 1.3497, 1.1875, and 1.1222, respectively. So the estimate definitely depends on which estimator is used. If one of these three estimators were unbiased and the other two were biased, there would be a good case for using the unbiased one. But all three are unbiased; the argument relies on the fact that each one is a linear function of the Yi’s (we are assuming here that the xi’s are fixed, not random): 1 Y nb 1 E(Yi) 1 bxi 1 E a g ib 5 g 5b 5 g 5 gb 5 n xi n xi n xi n n Ea Ea gYi 1 1 1 b 5 E QgYiR 5 QgbxiR 5 b QgxiR 5 b gxi gxi gxi gxi gxiYi 1 1 1 b 5 E QgxiYiR 5 Qgxi bxiR 5 b Qgx 2i R 5 b 2 2 2 gxi gx i gx i gx 2i ■ In both the foregoing example and the situation involving estimating a normal population mean, the principle of unbiasedness (preferring an unbiased estimator to a biased one) cannot be invoked to select an estimator. What we now need is a criterion for choosing among unbiased estimators. Estimators with Minimum Variance Suppose û1 and û2 are two estimators of u that are both unbiased. Then, although the distribution of each estimator is centered at the true value of u, the spreads of the distributions about the true value may be different. Principle of Minimum Variance Unbiased Estimation Among all estimators of u that are unbiased, choose the one that has minimum variance. The resulting û is called the minimum variance unbiased estimator (MVUE) of u. Figure 6.3 pictures the pdf’s of two unbiased estimators, with û1 having smaller variance than û2. Then û1 is more likely than û2 to produce an estimate close to the true u. The MVUE is, in a certain sense, the most likely among all unbiased estimators to produce an estimate close to the true u. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 248 CHAPTER 6 Point Estimation pdf of ␪^1 pdf of ␪^2 ␪ Figure 6.3 Graphs of the pdf’s of two different unbiased estimators In Example 6.5, suppose each Yi is normally distributed with mean bxi and variance s2 (the assumption of constant variance). Then it can be shown that the third estimator b̂ 5 gxiYi /g x 2i not only has smaller variance than either of the other two unbiased estimators, but in fact is the MVUE—it has smaller variance than any other unbiased estimator of b. Example 6.6 We argued in Example 6.4 that when X1, . . . , Xn is a random sample from a uniform distribution on [0, u], the estimator û1 5 n11 n # max (X1 , c, X n) is unbiased for u (we previously denoted this estimator by û2). This is not the only unbiased estimator of u. The expected value of a uniformly distributed rv is just the midpoint of the interval of positive density, so E(Xi) ⫽ u/2. This implies that E(X) ⫽ u/2, from which E(2 X) ⫽ u. That is, the estimator û2 5 2X is unbiased for u. If X is uniformly distributed on the interval from A to B, then V(X) ⫽ s2 ⫽ (B ⫺ A)2/12. Thus, in our situation, V(Xi) ⫽ u2/12, V( X) ⫽ s2/n ⫽ u2/(12n), and V(û2) 5 V(2X ) 5 4V(X) 5 u2/(3n). The results of Exercise 32 can be used to show that V(û1) 5 u 2/[n(n 1 2)]. The estimator û1 has smaller variance than does û2 if 3n⬍ n(n ⫹ 2)—that is, if 0 ⬍ n2 ⫺ n ⫽ n(n ⫺ 1). As long as n ⬎ 1, V(û1) , V(û2), so û1 is a better estimator than û2. More advanced methods can be used to show that û1 is the MVUE of u—every other unbiased estimator of u has variance that exceeds u 2/[n(n ⫹ 2)]. ■ One of the triumphs of mathematical statistics has been the development of methodology for identifying the MVUE in a wide variety of situations. The most important result of this type for our purposes concerns estimating the mean m of a normal distribution. THEOREM Let X1, . . . , Xn be a random sample from a normal distribution with parameters m and s. Then the estimator m̂ 5 X is the MVUE for m. Whenever we are convinced that the population being sampled is normal, the theorem says that x苶 should be used to estimate m. In Example 6.2, then, our estimate would be 苶x ⫽ 27.793. In some situations, it is possible to obtain an estimator with small bias that would be preferred to the best unbiased estimator. This is illustrated in Figure 6.4. However, MVUEs are often easier to obtain than the type of biased estimator whose distribution is pictured. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6.1 Some General Concepts of Point Estimation 249 pdf of ␪^1, a biased estimator pdf of ␪^2, the MVUE ␪ Figure 6.4 A biased estimator that is preferable to the MVUE Some Complications The last theorem does not say that in estimating a population mean m, the estimator X should be used irrespective of the distribution being sampled. Example 6.7 Suppose we wish to estimate the thermal conductivity m of a certain material. Using standard measurement techniques, we will obtain a random sample X1, . . . , Xn of n thermal conductivity measurements. Let’s assume that the population distribution is a member of one of the following three families: 1 2 2 e2(x2m) /(2s ) 2` , x , ` 12ps2 1 f(x) 5 2` , x , ` p[1 1 (x 2 m)2] f (x) 5 1 f (x) 5 u 2c 0 2c # x 2 m # c (6.1) (6.2) (6.3) otherwise The pdf (6.1) is the normal distribution, (6.2) is called the Cauchy distribution, and (6.3) is a uniform distribution. All three distributions are symmetric about m, and in fact the Cauchy distribution is bell-shaped but with much heavier tails (more probability farther out) than the normal curve. The uniform distribution has no tails. The | four estimators for m considered earlier are X, X, Xe (the average of the two extreme observations), and Xtr(10), a trimmed mean. The very important moral here is that the best estimator for m depends crucially on which distribution is being sampled. In particular, 1. If the random sample comes from a normal distribution, then X is the best of the four estimators, since it has minimum variance among all unbiased estimators. 2. If the random sample comes from a Cauchy distribution, then X and Xe are terrible | estimators for m, whereas X is quite good (the MVUE is not known); X is bad because it is very sensitive to outlying observations, and the heavy tails of the Cauchy distribution make a few such observations likely to appear in any sample. 3. If the underlying distribution is uniform, the best estimator is Xe; this estimator is greatly influenced by outlying observations, but the lack of tails makes such observations impossible. 4. The trimmed mean is best in none of these three situations but works reasonably well in all three. That is, Xtr(10) does not suffer too much in comparison with the best procedure in any of the three situations. ■ More generally, recent research in statistics has established that when estimating a point of symmetry m of a continuous probability distribution, a trimmed mean with trimming proportion 10% or 20% (from each end of the sample) produces reasonably Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 250 CHAPTER 6 Point Estimation behaved estimates over a very wide range of possible models. For this reason, a trimmed mean with small trimming percentage is said to be a robust estimator. In some situations, the choice is not between two different estimators constructed from the same sample, but instead between estimators based on two different experiments. Example 6.8 Suppose a certain type of component has a lifetime distribution that is exponential with parameter l so that expected lifetime is m ⫽ 1/l. A sample of n such components is selected, and each is put into operation. If the experiment is continued until all n lifetimes, X1, . . . , Xn, have been observed, then X is an unbiased estimator of m. In some experiments, though, the components are left in operation only until the time of the rth failure, where r ⬍ n. This procedure is referred to as censoring. Let Y1 denote the time of the first failure (the minimum lifetime among the n components), Y2 denote the time at which the second failure occurs (the second smallest lifetime), and so on. Since the experiment terminates at time Yr, the total accumulated lifetime at termination is r Tr 5 g Yi 1 (n 2 r)Yr i51 We now demonstrate that m̂ 5 Tr /r is an unbiased estimator for m. To do so, we need two properties of exponential variables: 1. The memoryless property (see Section 4.4), which says that at any time point, remaining lifetime has the same exponential distribution as original lifetime. 2. When X1, . . . , Xk are independent, each exponentially distributed with parameter l, min(X1, . . . , Xk), is exponential with parameter kl. Since all n components last until Y1, n ⫺ 1 last an additional Y2 ⫺ Y1, n ⫺ 2 an additional Y3 ⫺ Y2 amount of time, and so on, another expression for Tr is Tr ⫽ nY1 ⫹ (n ⫺ 1)(Y2 ⫺ Y1) ⫹ (n ⫺ 2)(Y3 ⫺ Y2) ⫹ . . . ⫹ (n ⫺ r ⫹ 1)(Yr ⫺ Yr ⫺ 1) But Y1 is the minimum of n exponential variables, so E(Y1) ⫽ 1/(nl). Similarly, Y2 ⫺ Y1 is the smallest of the n ⫺ 1 remaining lifetimes, each exponential with parameter l (by the memoryless property), so E(Y2 ⫺ Y1) ⫽ 1/[(n ⫺ 1)l]. Continuing, E(Yi ⫹ 1 ⫺ Yi) ⫽ 1/[(n ⫺ i)l], so E(Tr) ⫽ nE(Y1) ⫹ (n ⫺ 1)E(Y2 ⫺ Y1) ⫹ . . . ⫹ (n ⫺ r ⫹ 1)E(Yr ⫺ Yr ⫺ 1) 5n 5 # 1 1 (n 2 1) nl # 1 1 c 1 (n 2 r 1 1) (n 2 1)l # 1 (n 2 r 1 1)l r l Therefore, E(Tr /r) ⫽ (1/r)E(Tr) ⫽ (1/r) ⭈ (r/l) ⫽ 1/l ⫽ m as claimed. As an example, suppose 20 components are tested and r ⫽ 10. Then if the first ten failure times are 11, 15, 29, 33, 35, 40, 47, 55, 58, and 72, the estimate of m is 11 1 15 1 c 1 72 1 (10)(72) 5 111.5 m̂ 5 10 The advantage of the experiment with censoring is that it terminates more quickly than the uncensored experiment. However, it can be shown that V(Tr /r) ⫽ 1/(l2r), which is larger than 1/(l2n), the variance of X in the uncensored experiment. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6.1 Some General Concepts of Point Estimation 251 Reporting a Point Estimate: The Standard Error Besides reporting the value of a point estimate, some indication of its precision should be given. The usual measure of precision is the standard error of the estimator used. DEFINITION Example 6.9 (Example 6.2 continued) Example 6.10 (Example 6.1 continued) The standard error of an estimator û is its standard deviation sû 5 1V( û ). It is the magnitude of a typical or representative deviation between an estimate and the value of u. If the standard error itself involves unknown parameters whose values can be estimated, substitution of these estimates into sû yields the estimated standard error (estimated standard deviation) of the estimator. The estimated standard error can be denoted either by ŝû (the ˆ over s emphasizes that sû is being estimated) or by sû . Assuming that breakdown voltage is normally distributed, m̂ 5 X is the best estimator of m. If the value of s is known to be 1.5, the standard error of X is s2X 5 s/ 1n 5 1.5/ 120 5 .335. If, as is usually the case, the value of s is unknown, the estimate ŝ 5 s 5 1.462 is substituted into s2 X to obtain the esti2 mated standard error ŝ2 . ■ 5 s 5 s/1n 5 1.462/120 5 .327 X X The standard error of p̂ ⫽ X/n is sp̂ 5 2V(X/n) 5 V(X) npq pq 5 5 B n2 B n2 Bn Since p and q ⫽ 1 ⫺ p are unknown (else why estimate?), we substitute p̂ ⫽ x/n and q̂ ⫽ 1 ⫺ x/n into sp̂, yielding the estimated standard error ŝp̂ 5 1p̂q̂/n 5 1(.6)(.4)/25 5 .098. Alternatively, since the largest value of pq is attained when p ⫽ q ⫽ .5, an upper bound on the standard error is 11/(4n) 5 .10. ■ When the point estimator û has approximately a normal distribution, which will often be the case when n is large, then we can be reasonably confident that the true value of u lies within approximately 2 standard errors (standard deviations) of û. Thus if a sample of n ⫽ 36 component lifetimes gives m̂ 5 x 5 28.50 and s ⫽ 3.60, then s/1n 5 .60, so within 2 estimated standard errors, m̂ translates to the interval 28.50 ⫾ (2)(.60) ⫽ (27.30, 29.70). If û is not necessarily approximately normal but is unbiased, then it can be shown that the estimate will deviate from u by as much as 4 standard errors at most 6% of the time. We would then expect the true value to lie within 4 standard errors of û (and this is a very conservative statement, since it applies to any unbiased û). Summarizing, the standard error tells us roughly within what distance of û we can expect the true value of u to lie. The form of the estimator û may be sufficiently complicated so that standard statistical theory cannot be applied to obtain an expression for sû. This is true, for example, in the case u ⫽ s, û 5 S; the standard deviation of the statistic S, sS, cannot in general be determined. In recent years, a new computer-intensive method called the bootstrap has been introduced to address this problem. Suppose that the population pdf is f (x; u), a member of a particular parametric family, and that data x1, x2, . . . , xn gives û 5 21.7. We now use the computer to obtain “bootstrap samples” from the pdf f(x; 21.7), and for each sample we calculate a “bootstrap estimate” û*: Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 252 Point Estimation CHAPTER 6 First bootstrap sample: x*1, x*2 , c, x *; n estimate 5 û* 1 *, Second bootstrap sample: x*1 , x2 c, x*; n estimate 5 û* 2 ( Bth bootstrap sample: x*, 1 x* 2 , c, x* n ; estimate 5 û* B B ⫽ 100 or 200 is often used. Now let u# * 5 ⌺û*i /B, the sample mean of the bootstrap estimates. The bootstrap estimate of û ’s standard error is now just the sample standard deviation of the û*i ’s: Sû 5 1 g(û*i 2 u*)2 BB 2 1 (In the bootstrap literature, B is often used in place of B ⫺ 1; for typical values of B, there is usually little difference between the resulting estimates.) Example 6.11 A theoretical model suggests that X, the time to breakdown of an insulating fluid between electrodes at a particular voltage, has f(x; l) ⫽ le⫺lx, an exponential distribution. A random sample of n ⫽ 10 breakdown times (min) gives the following data: 41.53 18.73 2.99 30.34 12.33 117.52 73.02 223.63 4.00 26.78 Since E(X) ⫽ 1/l, E(X) ⫽ 1/l, so a reasonable estimate of l is l̂ 5 1/ x 5 1/55.087 5 .018153. We then used a statistical computer package to obtain B ⫽ 100 bootstrap samples, each of size 10, from f(x; .018153). The first such sample was 41.00, 109.70, 16.78, 6.31, 6.76, 5.62, 60.96, 78.81, 192.25, 27.61, from which g x*i 5 545.8 and l̂*1 5 1/54.58 5 .01832. The average of the 100 bootstrap estimates is l# * 5 .02153, and the sample standard deviation of these 100 estimates is slˆ 5 .0091, the bootstrap estimate of l̂ ’s standard error. A histogram of the 100 l̂i*’s was somewhat positively skewed, suggesting that the sampling distribution of l̂ also has this property. ■ Sometimes an investigator wishes to estimate a population characteristic without assuming that the population distribution belongs to a particular parametric family. An instance of this occurred in Example 6.7, where a 10% trimmed mean was proposed for estimating a symmetric population distribution’s center u. The data of Example 6.2 gave û 5 x# tr(10) 5 27.838, but now there is no assumed f (x; u), so how can we obtain a bootstrap sample? The answer is to regard the sample itself as constituting the population (the n ⫽ 20 observations in Example 6.2) and take B different samples, each of size n, with replacement from this population. The book by Bradley Efron and Robert Tibshirani or the one by John Rice listed in the chapter bibliography provides more information. EXERCISES Section 6.1 (1–19) 1. The accompanying data on flexural strength (MPa) for concrete beams of a certain type was introduced in Example 1.2. 5.9 7.2 7.3 6.3 8.1 6.8 7.0 7.6 6.8 6.5 7.0 6.3 7.9 9.0 8.2 8.7 7.8 9.7 7.4 7.7 9.7 7.8 7.7 11.6 11.3 11.8 10.7 a. Calculate a point estimate of the mean value of strength for the conceptual population of all beams manufactured in this fashion, and state which estimator you used. [Hint: ⌺xi ⫽ 219.8.] b. Calculate a point estimate of the strength value that separates the weakest 50% of all such beams from the strongest 50%, and state which estimator you used. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6.1 Some General Concepts of Point Estimation c. Calculate and interpret a point estimate of the population standard deviation s. Which estimator did you use? [Hint: gx 2i 5 1860.94.] d. Calculate a point estimate of the proportion of all such beams whose flexural strength exceeds 10 MPa. [Hint: Think of an observation as a “success” if it exceeds 10.] e. Calculate a point estimate of the population coefficient of variation s/m, and state which estimator you used. 2. A sample of 20 students who had recently taken elementary statistics yielded the following information on the brand of calculator owned (T ⫽ Texas Instruments, H ⫽ Hewlett Packard, C ⫽ Casio, S ⫽ Sharp): T T H T C H S H C T T T H T S T C T T S a. Estimate the true proportion of all such students who own a Texas Instruments calculator. b. Of the 10 students who owned a TI calculator, 4 had graphing calculators. Estimate the proportion of students who do not own a TI graphing calculator. 3. Consider the following sample of observations on coating thickness for low-viscosity paint (“Achieving a Target Value for a Manufacturing Process: A Case Study,” J. of Quality Technology, 1992: 22–26): .83 .88 .88 1.04 1.09 1.12 1.29 1.31 1.48 1.49 1.59 1.62 1.65 1.71 1.76 1.83 Assume that the distribution of coating thickness is normal (a normal probability plot strongly supports this assumption). a. Calculate a point estimate of the mean value of coating thickness, and state which estimator you used. b. Calculate a point estimate of the median of the coating thickness distribution, and state which estimator you used. c. Calculate a point estimate of the value that separates the largest 10% of all values in the thickness distribution from the remaining 90%, and state which estimator you used. [Hint: Express what you are trying to estimate in terms of m and s.] d. Estimate P(X ⬍ 1.5), i.e., the proportion of all thickness values less than 1.5. [Hint: If you knew the values of m and s, you could calculate this probability. These values are not available, but they can be estimated.] e. What is the estimated standard error of the estimator that you used in part (b)? 4. The article from which the data in Exercise 1 was extracted also gave the accompanying strength observations for cylinders: 6.1 5.8 7.8 7.1 7.2 9.2 6.6 7.8 8.1 7.4 8.5 8.9 9.8 9.7 8.3 7.0 8.3 14.1 12.6 11.2 Prior to obtaining data, denote the beam strengths by X1, . . . , Xm and the cylinder strengths by Y1, . . . , Yn. Suppose that the Xi’s constitute a random sample from a distribution with mean m1 and standard deviation s1 and that the Yi’s form a random sample (independent of the Xi’s) from another distribution with mean m2 and standard deviation s2. 253 a. Use rules of expected value to show that X ⫺ Y is an unbiased estimator of m1 ⫺ m2. Calculate the estimate for the given data. b. Use rules of variance from Chapter 5 to obtain an expression for the variance and standard deviation (standard error) of the estimator in part (a), and then compute the estimated standard error. c. Calculate a point estimate of the ratio s1/s2 of the two standard deviations. d. Suppose a single beam and a single cylinder are randomly selected. Calculate a point estimate of the variance of the difference X ⫺ Y between beam strength and cylinder strength. 5. As an example of a situation in which several different statistics could reasonably be used to calculate a point estimate, consider a population of N invoices. Associated with each invoice is its “book value,” the recorded amount of that invoice. Let T denote the total book value, a known amount. Some of these book values are erroneous. An audit will be carried out by randomly selecting n invoices and determining the audited (correct) value for each one. Suppose that the sample gives the following results (in dollars). Invoice Book value Audited value Error 1 2 3 4 5 300 300 0 720 520 200 526 526 0 200 200 0 127 157 ᎐30 Let Y ⫽ sample mean book value X ⫽ sample mean audited value D ⫽ sample mean error Propose three different statistics for estimating the total audited (i.e., correct) value—one involving just N and X, another involving T, N, and D, and the last involving T and X/Y. If N ⫽ 5000 and T ⫽ 1,761,300, calculate the three corresponding point estimates. (The article “Statistical Models and Analysis in Auditing,” Statistical Science, 1989: 2–33 discusses properties of these estimators.) 6. Consider the accompanying observations on stream flow (1000s of acre-feet) recorded at a station in Colorado for the period April 1–August 31 over a 31-year span (from an article in the 1974 volume of Water Resources Research). 127.96 210.07 203.24 108.91 178.21 285.37 100.85 200.19 89.59 185.36 126.94 66.24 247.11 299.87 109.64 125.86 114.79 109.11 330.33 85.54 117.64 302.74 280.55 145.11 95.36 204.91 311.13 150.58 262.09 477.08 94.33 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 254 CHAPTER 6 Point Estimation An appropriate probability plot supports the use of the lognormal distribution (see Section 4.5) as a reasonable model for stream flow. a. Estimate the parameters of the distribution. [Hint: Remember that X has a lognormal distribution with parameters m and s 2 if ln(X) is normally distributed with mean m and variance s 2.] b. Use the estimates of part (a) to calculate an estimate of the expected value of stream flow. [Hint: What is E(X)?] 7. a. A random sample of 10 houses in a particular area, each of which is heated with natural gas, is selected and the amount of gas (therms) used during the month of January is determined for each house. The resulting observations are 103, 156, 118, 89, 125, 147, 122, 109, 138, 99. Let m denote the average gas usage during January by all houses in this area. Compute a point estimate of m. b. Suppose there are 10,000 houses in this area that use natural gas for heating. Let t denote the total amount of gas used by all of these houses during January. Estimate t using the data of part (a). What estimator did you use in computing your estimate? c. Use the data in part (a) to estimate p, the proportion of all houses that used at least 100 therms. d. Give a point estimate of the population median usage (the middle value in the population of all houses) based on the sample of part (a). What estimator did you use? 8. In a random sample of 80 components of a certain type, 12 are found to be defective. a. Give a point estimate of the proportion of all such components that are not defective. b. A system is to be constructed by randomly selecting two of these components and connecting them in series, as shown here. The series connection implies that the system will function if and only if neither component is defective (i.e., both components work properly). Estimate the proportion of all such systems that work properly. [Hint: If p denotes the probability that a component works properly, how can P(system works) be expressed in terms of p?] 9. Each of 150 newly manufactured items is examined and the number of scratches per item is recorded (the items are supposed to be free of scratches), yielding the following data: Number of scratches per item 0 1 2 3 4 5 6 7 Observed frequency 18 37 42 30 13 7 2 1 Let X ⫽ the number of scratches on a randomly chosen item, and assume that X has a Poisson distribution with parameter m. a. Find an unbiased estimator of m and compute the estimate for the data. [Hint: E(X) ⫽ m for X Poisson, so E( X ) ⫽ ?] b. What is the standard deviation (standard error) of your estimator? Compute the estimated standard error. [Hint: s2X 5 m for X Poisson.] 10. Using a long rod that has length m, you are going to lay out a square plot in which the length of each side is m. Thus the area of the plot will be m2. However, you do not know the value of m, so you decide to make n independent measurements X1, X2, . . . , Xn of the length. Assume that each Xi has mean m (unbiased measurements) and variance s2. a. Show that X 2 is not an unbiased estimator for m2. [Hint: For any rv Y, E(Y 2) ⫽ V(Y) ⫹ [E(Y)]2. Apply this with Y ⫽ X.] b. For what value of k is the estimator X 2 ⫺ kS 2 unbiased for m2? [Hint: Compute E(X 2 ⫺ kS 2).] 11. Of n1 randomly selected male smokers, X1 smoked filter cigarettes, whereas of n2 randomly selected female smokers, X2 smoked filter cigarettes. Let p1 and p2 denote the probabilities that a randomly selected male and female, respectively, smoke filter cigarettes. a. Show that (X1/n1) ⫺ (X2/n2) is an unbiased estimator for p1 ⫺ p2. [Hint: E(Xi ) ⫽ ni pi for i ⫽ 1, 2.] b. What is the standard error of the estimator in part (a)? c. How would you use the observed values x1 and x2 to estimate the standard error of your estimator? d. If n1 ⫽ n2 ⫽ 200, x1 ⫽ 127, and x2 ⫽ 176, use the estimator of part (a) to obtain an estimate of p1 ⫺ p2. e. Use the result of part (c) and the data of part (d) to estimate the standard error of the estimator. 12. Suppose a certain type of fertilizer has an expected yield per acre of m1 with variance s2, whereas the expected yield for a second type of fertilizer is m2 with the same variance s2. Let S 21 and S 22 denote the sample variances of yields based on sample sizes n1 and n2, respectively, of the two fertilizers. Show that the pooled (combined) estimator ŝ2 5 (n1 2 1)S12 1 (n2 2 1)S22 n1 1 n2 2 2 is an unbiased estimator of s2. 13. Consider a random sample X1, . . . , Xn from the pdf f(x; u) ⫽ .5(1 ⫹ ux) ⫺1 ⱕ x ⱕ 1 where ⫺1 ⱕ u ⱕ 1 (this distribution arises in particle physics). Show that û 5 3X is an unbiased estimator of u. [Hint: First determine m ⫽ E(X) ⫽ E(X).] 14. A sample of n captured Pandemonium jet fighters results in serial numbers x1, x2, x3, . . . , xn. The CIA knows that the aircraft were numbered consecutively at the factory starting with a and ending with b, so that the total number of planes manufactured is b ⫺ a ⫹ 1 (e.g., if a ⫽ 17 and b ⫽ 29, then 29 ⫺ 17 ⫹ 1 ⫽ 13 planes having serial numbers 17, 18, 19, . . . , 28, 29 were manufactured). However, the CIA does not know the values of a or b. A CIA statistician suggests using the Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6.2 Methods of Point Estimation estimator max(Xi ) ⫺ min(Xi ) ⫹ 1 to estimate the total number of planes manufactured. a. If n ⫽ 5, x1 ⫽ 237, x2 ⫽ 375, x3 ⫽ 202, x4 ⫽ 525, and x5 ⫽ 418, what is the corresponding estimate? b. Under what conditions on the sample will the value of the estimate be exactly equal to the true total number of planes? Will the estimate ever be larger than the true total? Do you think the estimator is unbiased for estimating b ⫺ a ⫹ 1? Explain in one or two sentences. 15. Let X1, X2, . . . , Xn represent a random sample from a Rayleigh distribution with pdf f(x; u) 5 x 2x2/(2u) e x.0 u a. It can be shown that E(X 2) ⫽ 2u. Use this fact to construct an unbiased estimator of u based on gX 2i (and use rules of expected value to show that it is unbiased). b. Estimate u from the following n ⫽ 10 observations on vibratory stress of a turbine blade under specified conditions: 16.88 10.23 4.59 6.66 13.68 14.23 19.87 9.40 6.51 10.95 16. Suppose the true average growth m of one type of plant during a 1-year period is identical to that of a second type, but the variance of growth for the first type is s 2, whereas for the second type the variance is 4s 2. Let X1, . . . , Xm be m independent growth observations on the first type [so E(Xi ) ⫽ m, V(X i ) ⫽ s 2], and let Y1, . . . , Yn be n independent growth observations on the second type [E(Yi ) ⫽ m, V(Yi ) ⫽ 4s2]. a. Show that for any d between 0 and 1, the estimator m̂ 5 dX 1 (1 2 d)Y is unbiased for m. b. For fixed m and n, compute V(m̂), and then find the value of d that minimizes V(m̂). [Hint: Differentiate V(m̂) with respect to d.] 17. In Chapter 3, we defined a negative binomial rv as the number of failures that occur before the rth success in a sequence of independent and identical success/failure trials. The probability mass function (pmf) of X is nb(x; r, p) ⫽ a x1r21 b pr(1 2 p)x x 5 0, 1, 2, . . . x 255 a. Suppose that r ⱖ 2. Show that p̂ ⫽ (r ⫺ 1)/(X ⫹ r ⫺ 1) is an unbiased estimator for p. [Hint: Write out E( p̂ ) and cancel x ⫹ r ⫺ 1 inside the sum.] b. A reporter wishing to interview five individuals who support a certain candidate begins asking people whether (S) or not (F) they support the candidate. If the sequence of responses is SFFSFFFSSS, estimate p ⫽ the true proportion who support the candidate. 18. Let X1, X2, . . . , Xn be a random sample from a pdf f (x) that | is an unbiased estimator of is symmetric about m, so that X | ) ⬇ 1/(4n[ f(m)]2). m. If n is large, it can be shown that V( X | a. Compare V(X) to V(X ) when the underlying distribution is normal. b. When the underlying pdf is Cauchy (see Example 6.7), | ) in V( X ) ⫽ ` , so X is a terrible estimator. What is V( X this case when n is large? 19. An investigator wishes to estimate the proportion of students at a certain university who have violated the honor code. Having obtained a random sample of n students, she realizes that asking each, “Have you violated the honor code?” will probably result in some untruthful responses. Consider the following scheme, called a randomized response technique. The investigator makes up a deck of 100 cards, of which 50 are of type I and 50 are of type II. Type I: Have you violated the honor code (yes or no)? Type II: Is the last digit of your telephone number a 0, 1, or 2 (yes or no)? Each student in the random sample is asked to mix the deck, draw a card, and answer the resulting question truthfully. Because of the irrelevant question on type II cards, a yes response no longer stigmatizes the respondent, so we assume that responses are truthful. Let p denote the proportion of honor-code violators (i.e., the probability of a randomly selected student being a violator), and let l ⫽ P(yes response). Then l and p are related by l ⫽ .5p ⫹ (.5)(.3). a. Let Y denote the number of yes responses, so Y ⬃ Bin (n, l). Thus Y/n is an unbiased estimator of l. Derive an estimator for p based on Y. If n ⫽ 80 and y ⫽ 20, what is your estimate? [Hint: Solve l ⫽ .5p ⫹ .15 for p and then substitute Y/n for l.] b. Use the fact that E(Y/n) ⫽ l to show that your estimator p̂ is unbiased. c. If there were 70 type I and 30 type II cards, what would be your estimator for p? 6.2 Methods of Point Estimation The definition of unbiasedness does not in general indicate how unbiased estimators can be derived. We now discuss two “constructive” methods for obtaining point estimators: the method of moments and the method of maximum likelihood. By constructive we mean that the general definition of each type of estimator suggests explicitly how to Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 256 CHAPTER 6 Point Estimation obtain the estimator in any specific problem. Although maximum likelihood estimators are generally preferable to moment estimators because of certain efficiency properties, they often require significantly more computation than do moment estimators. It is sometimes the case that these methods yield unbiased estimators. The Method of Moments The basic idea of this method is to equate certain sample characteristics, such as the mean, to the corresponding population expected values. Then solving these equations for unknown parameter values yields the estimators. DEFINITION Let X1, . . . , Xn be a random sample from a pmf or pdf f(x). For k ⫽ 1, 2, 3, . . . , the kth population moment, or kth moment of the distribution f(x), is E(X k ). The kth sample moment is (1/n)g ni51X ki . Thus the first population moment is E (X) ⫽ m, and the first sample moment is ⌺Xi /n ⫽ X . The second population and sample moments are E(X 2) and gX i2/n, respectively. The population moments will be functions of any unknown parameters u1, u2, . . . . DEFINITION Let X1, X2, . . . , Xn be a random sample from a distribution with pmf or pdf f(x; u1, . . . , um ), where u1, . . . , u m are parameters whose values are unknown. Then the moment estimators û1, c, ûm are obtained by equating the first m sample moments to the corresponding first m population moments and solving for u1, . . . , u m. If, for example, m ⫽ 2, E(X) and E(X 2 ) will be functions of u1 and u2. Setting E(X) ⫽ (1/n) ⌺Xi (⫽ X ) and E(X 2 ) 5 (1/n)gX 2i gives two equations in u1 and u2. The solution then defines the estimators. Example 6.12 Let X1, X2 , . . . , Xn represent a random sample of service times of n customers at a certain facility, where the underlying distribution is assumed exponential with parameter l. Since there is only one parameter to be estimated, the estimator is obtained by equating E(X ) to X . Since E(X ) ⫽ 1/l for an exponential distribution, this gives 1/l ⫽ X or l ⫽ 1/ X . The moment estimator of l is then l̂ 5 1/X.. ■ Example 6.13 Let X1, . . . , Xn be a random sample from a gamma distribution with parameters a and b. From Section 4.4, E(X ) ⫽ ab and E(X 2 ) ⫽ b 2⌫(a ⫹ 2)/⌫(a) ⫽ b 2(a ⫹ 1)a. The moment estimators of a and b are obtained by solving X 5 ab 1 gX 2i 5 a(a 1 1)b2 n 2 Since a(a ⫹ 1)b 2 ⫽ a 2b 2 ⫹ ab 2 and the first equation implies a 2b 2 ⫽ X , the second equation becomes 1 2 gX 2i 5 X 1 ab2 n Now dividing each side of this second equation by the corresponding side of the first equation and substituting back gives the estimators Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6.2 Methods of Point Estimation â 5 X2 (1/n)gX 2i 2 X 2 (1/n)gX 2i 2 X X b̂ 5 257 2 To illustrate, the survival-time data mentioned in Example 4.24 is 152 115 125 40 109 94 88 137 152 128 123 136 101 77 160 165 62 153 83 69 with x ⫽ 113.5 and (1/20)g x 2i 5 14,087.8. The estimates are (113.5)2 5 10.7 14,087.8 2 (113.5)2 â 5 14,087.8 2 (113.5)2 bˆ 5 5 10.6 113.5 These estimates of a and b differ from the values suggested by Gross and Clark because they used a different estimation technique. ■ Example 6.14 Let X1, . . . , Xn be a random sample from a generalized negative binomial distribution with parameters r and p (see Section 3.5). Since E(X) ⫽ r(1 ⫺ p)/p and V(X) ⫽ r(1 ⫺ p)/p2, E(X 2) ⫽ V(X) ⫹ [E(X )]2 ⫽ r(1 ⫺ p)(r ⫺ rp ⫹ 1)/p2. Equating E(X ) to X and E(X 2) to (1/n)gX 2i eventually gives p̂ 5 X (1/n)gX i2 2 X 2 r̂ 5 X2 (1/n)gX i2 2 X 2 2 X As an illustration, Reep, Pollard, and Benjamin (“Skill and Chance in Ball Games,” J. of Royal Stat. Soc., 1971: 623–629) consider the negative binomial distribution as a model for the number of goals per game scored by National Hockey League teams. The data for 1966–1967 follows (420 games): Goals 0 1 2 3 4 5 6 7 8 9 10 Frequency 29 71 82 89 65 45 24 7 4 1 3 Then, x ⫽ ⌺xi /420 ⫽ [(0)(29) ⫹ (1)(71) ⫹ . . . ⫹ (10)(3)]/420 ⫽ 2.98 and gx 2i /420 5 [(0)2(29) 1 (1)2(71) 1 c 1 (10)2(3)]/420 5 12.40 Thus, p̂ 5 2.98 5 .85 12.40 2 (2.98)2 r̂ 5 (2.98)2 5 16.5 12.40 2 (2.98)2 2 2.98 Although r by definition must be positive, the denominator of r̂ could be negative, indicating that the negative binomial distribution is not appropriate (or that the moment estimator is flawed). ■ Maximum Likelihood Estimation The method of maximum likelihood was first introduced by R. A. Fisher, a geneticist and statistician, in the 1920s. Most statisticians recommend this method, at least when the sample size is large, since the resulting estimators have certain desirable efficiency properties (see the proposition on page 262). Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 258 CHAPTER 6 Point Estimation Example 6.15 A sample of ten new bike helmets manufactured by a certain company is obtained. Upon testing, it is found that the first, third, and tenth helmets are flawed, whereas the others are not. Let p ⫽ P(flawed helmet), i.e., p is the proportion of all such helmets that are flawed. Define (Bernoulli) random variables X1, X2, c, X10 by X1 5 e 1 if 1st helmet is flawed ... 0 if 1st helmet isn’t flawed X10 5 e 1 if 10th helmet is flawed 0 if 10th helmet isn’t flawed Then for the obtained sample, X1 ⫽ X3 ⫽ X10 ⫽ 1 and the other seven Xi’s are all zero. The probability mass function of any particular Xi is pxi (1 ⫺ p)1⫺ xi , which becomes p if xi ⫽ 1 and 1 ⫺ p when xi ⫽ 0. Now suppose that the conditions of various helmets are independent of one another. This implies that the Xi’s are independent, so their joint probability mass function is the product of the individual pmf’s. Thus the joint pmf evaluated at the observed Xi’s is f(x1, . . . , x10; p) 5 p(1 2 p)p cp 5 p3(1 2 p)7 (6.4) Suppose that p ⫽ .25. Then the probability of observing the sample that we actually obtained is (.25)3(.75)7 ⫽ .002086. If instead p ⫽ .50, then this probability is (.50)3(.50)7 ⫽ .000977. For what value of p is the obtained sample most likely to have occurred? That is, for what value of p is the joint pmf (6.4) as large as it can be? What value of p maximizes (6.4)? Figure 6.5(a) shows a graph of the likelihood (6.4) as a function of p. It appears that the graph reaches its peak above p ⫽ .3 ⫽ the proportion of flawed helmets in the sample. Figure 6.5(b) shows a graph of the natural logarithm of (6.4); since ln[g(u)] is a strictly increasing function of g(u), finding u to maximize the function g(u) is the same as finding u to maximize ln[g(u)]. Likelihood ln(likelihood) 0.0025 0 0.0020 –10 0.0015 –20 0.0010 –30 0.0005 –40 0.0000 p 0.0 0.2 0.4 0.6 0.8 1.0 –50 p 0.0 0.2 0.4 0.6 0.8 1.0 Figure 6.5 (a) Graph of the likelihood (joint pmf) (6.4) from Example 6.15 (b) Graph of the natural logarithm of the likelihood We can verify our visual impression by using calculus to find the value of p that maximizes (6.4). Working with the natural log of the joint pmf is often easier than working with the joint pmf itself, since the joint pmf is typically a product so its logarithm will be a sum. Here ln[ f (x1, . . . , x10; p)] 5 ln[p3(1 2 p)7] 5 3ln(p) 1 7ln(1 2 p) (6.5) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6.2 Methods of Point Estimation 259 Thus d d 3 7 5ln[ f(x1, . . . , x10; p)]6 5 53ln(p) 1 7ln(1 2 p)6 5 1 (21) p dp dp 12p 3 7 5 2 p 12p [the (⫺1) comes from the chain rule in calculus]. Equating this derivative to 0 and solving for p gives 3(1 ⫺ p) ⫽ 7p, from which 3 ⫽ 10p and so p ⫽ 3/10 ⫽ .30 as conjectured. That is, our point estimate is p̂ ⫽ .30. It is called the maximum likelihood estimate because it is the parameter value that maximizes the likelihood (joint pmf) of the observed sample. In general, the second derivative should be examined to make sure a maximum has been obtained, but here this is obvious from Figure 6.5. Suppose that rather than being told the condition of every helmet, we had only been informed that three of the ten were flawed. Then we would have the observed value of a binomial random variable X ⫽ the number of flawed helmets. The pmf of X is A 10x B px (1 2 p)102x. For x ⫽ 3, this becomes A 103 B p3(1 2 p)7. The binomial coefficient A 103 B is irrelevant to the maximization, so again p̂ 5 .30. ■ DEFINITION Let X1, X2, . . . , Xn have joint pmf or pdf f(x1, x2, . . . , xn; u1, . . . , um) (6.6) where the parameters u1, . . . , um have unknown values. When x1, . . . , xn are the observed sample values and (6.6) is regarded as a function of u1, . . . , um, it is called the likelihood function. The maximum likelihood estimates (mle’s) û1, c, ûm are those values of the ui’s that maximize the likelihood function, so that f(x1, c, xn; û1, c, ûm) $ f (x1, c, xn; u1, c, um) for all u1, c, um When the Xi’s are substituted in place of the xi’s, the maximum likelihood estimators result. The likelihood function tells us how likely the observed sample is as a function of the possible parameter values. Maximizing the likelihood gives the parameter values for which the observed sample is most likely to have been generated—that is, the parameter values that “agree most closely” with the observed data. Example 6.16 Suppose X1, X2, . . . , Xn is a random sample from an exponential distribution with parameter l. Because of independence, the likelihood function is a product of the individual pdf’s: f (x1, . . . , xn; l) ⫽ (le⫺lx1) ⭈ . . . ⭈ (le⫺lxn) ⫽ lne⫺l⌺xi The natural logarithm of the likelihood function is ln[ f (x1, . . . , xn ; l)] ⫽ n ln(l) ⫺ l⌺xi Equating (d/dl)[ln(likelihood)] to zero results in n/l ⫺ ⌺xi ⫽ 0, or l ⫽ n/ ⌺xi ⫽ 1/x. Thus the mle is l̂ 5 1/X; it is identical to the method of moments estimator [but it is not an unbiased estimator, since E(1/ X ) ⬆ 1/E( X )]. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 260 CHAPTER 6 Point Estimation Example 6.17 Let X1, . . . , Xn be a random sample from a normal distribution. The likelihood function is 1 1 2 2 2 2 e2(x12m) /(2s ) # c # e2(xn2m) /(2s ) 12ps2 12ps2 1 n/2 2g(xi2m)2/(2s2) 5 a b e 2ps2 f (x1, c, xn; m, s2) 5 so ln[f(x1, c, xn; m, s2)] 5 2 n 1 ln (2ps2) 2 g(xi 2 m)2 2 2s2 To find the maximizing values of m and s2, we must take the partial derivatives of ln( f ) with respect to m and s2, equate them to zero, and solve the resulting two equations. Omitting the details, the resulting mle’s are m̂ 5 X ŝ2 5 g(Xi 2 X)2 n The mle of s2 is not the unbiased estimator, so two different principles of estimation (unbiasedness and maximum likelihood) yield two different estimators. ■ Example 6.18 In Chapter 3, we mentioned the use of the Poisson distribution for modeling the number of “events” that occur in a two-dimensional region. Assume that when the region R being sampled has area a(R), the number X of events occurring in R has a Poisson distribution with parameter la(R) (where l is the expected number of events per unit area) and that nonoverlapping regions yield independent X’s. Suppose an ecologist selects n nonoverlapping regions R1, . . . , Rn and counts the number of plants of a certain species found in each region. The joint pmf (likelihood) is then [l # a(R1)]x1e2l # a(R1) # c # [l # a(Rn)]xne2l # a(Rn) x1! xn! x1 # c # xn # g xi # 2lg a(Ri) [a(Rn)] l e [a(R1)] 5 c # # x! x! p(x1, c, xn; l) 5 1 n The ln(likelihood) is ln[ p(x1, . . . , xn; l)] ⫽ gxi ⴢ ln[a(Ri)] ⫹ ln(l) ⴢ gxi ⫺ lga(Ri ) ⫺ gln(xi!) Taking d/dl [ln(p)] and equating it to zero yields gxi 2 ga(Ri ) 5 0 l so l5 gxi ga(R i ) The mle is then l̂ 5 gXi /ga(Ri). This is intuitively reasonable because l is the true density (plants per unit area), whereas l̂ is the sample density since ⌺a(Ri) is just the total area sampled. Because E(Xi) ⫽ l ⴢ a(Ri), the estimator is unbiased. Sometimes an alternative sampling procedure is used. Instead of fixing regions to be sampled, the ecologist will select n points in the entire region Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6.2 Methods of Point Estimation 261 of interest and let yi ⫽ the distance from the ith point to the nearest plant. The cumulative distribution function (cdf) of Y ⫽ distance to the nearest plant is FY (y) 5 P(Y # y) 5 1 2 P(Y . y) 5 1 2 Pa no plants in a b circle of radius y 2 512 e2lpy (lpy2)0 5 1 2 e2l 0! # py 2 Taking the derivative of FY (y) with respect to y yields fY (y; l) 5 e 2 2plye2lpy 0 y$0 otherwise If we now form the likelihood f Y (y1; l) ⭈ . . . ⭈ fY ( yn; l), differentiate ln(likelihood), and so on, the resulting mle is l̂ 5 number of plants observed n 5 2 total area sampled pgY i which is also a sample density. It can be shown that in a sparse environment (small l), the distance method is in a certain sense better, whereas in a dense environment the first sampling method is better. ■ Example 6.19 Let X1, . . . , Xn be a random sample from a Weibull pdf a f(x; a, b) 5 • ba # x a21 # e2(x/b)a 0 x$0 otherwise Writing the likelihood and ln(likelihood), then setting both (⭸/⭸a)[ln(f )] ⫽ 0 and (⭸/⭸b)[ln( f )] ⫽ 0, yields the equations a5 c gx ai # ln (xi) gln(xi) d 2 a n gx i 21 b5 a gx ai 1/a b n These two equations cannot be solved explicitly to give general formulas for the mle’s â and b̂ . Instead, for each sample x1, . . . , xn, the equations must be solved using an iterative numerical procedure. Even moment estimators of a and b are somewhat complicated (see Exercise 21). ■ Estimating Functions of Parameters In Example 6.17, we obtained the mle of s2 when the underlying distribution is normal. The mle of s 5 1s2, as well as that of many other mle’s, can be easily derived using the following proposition. PROPOSITION The Invariance Principle Let û1, û2, c, ûm be the mle’s of the parameters u1, u2, . . . , um. Then the mle of any function h(u1, u2, . . . , um) of these parameters is the function h(û1, û2, c, ûm) of the mle’s. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 262 CHAPTER 6 Point Estimation Example 6.20 (Example 6.17 continued) In the normal case, the mle’s of m and s2 are m̂ ⫽ X and ŝ2 5 g(Xi 2 X )2/n. To obtain the mle of the function h(m, s2) 5 2s2 5 s, substitute the mle’s into the function: ŝ 5 2ŝ2 5 c 1/2 1 g(Xi 2 X)2 d n The mle of s is not the sample standard deviation S, though they are close unless n is quite small. ■ Example 6.21 The mean value of an rv X that has a Weibull distribution is (Example 6.19 continued) m ⫽ b ⭈ ⌫(1 ⫹ 1/a) The mle of m is therefore m̂ 5 b̂⌫(1 1 1/â), where â and b̂ are the mle’s of a and b. In particular, X is not the mle of m, though it is an unbiased estimator. At least for large n, m̂ is a better estimator than X. For the data given in Example 6.3, the mle’s of the Weibull parameters are â 5 11.9731 and b̂ 5 77.0153, from which m̂ 5 73.80. This estimate is quite close to the sample mean 73.88. ■ Large Sample Behavior of the MLE Although the principle of maximum likelihood estimation has considerable intuitive appeal, the following proposition provides additional rationale for the use of mle’s. PROPOSITION Under very general conditions on the joint distribution of the sample, when the sample size n is large, the maximum likelihood estimator of any parameter u is approximately unbiased [E(û) < u] and has variance that is either as small as or nearly as small as can be achieved by any estimator. Stated another way, the mle û is approximately the MVUE of u. Because of this result and the fact that calculus-based techniques can usually be used to derive the mle’s (though often numerical methods, such as Newton’s method, are necessary), maximum likelihood estimation is the most widely used estimation technique among statisticians. Many of the estimators used in the remainder of the book are mle’s. Obtaining an mle, however, does require that the underlying distribution be specified. Some Complications Sometimes calculus cannot be used to obtain mle’s. Example 6.22 Suppose my waiting time for a bus is uniformly distributed on [0, u] and the results x1, . . . , xn of a random sample from this distribution have been observed. Since f (x; u) ⫽ 1/u for 0 ⱕ x ⱕ u and 0 otherwise, 1 0 # x1 # u, c, 0 # xn # u f (x1, c, xn; u) 5 u un 0 otherwise Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 6.2 Methods of Point Estimation 263 Likelihood ␪ max(xi) Figure 6.6 The likelihood function for Example 6.22 As long as max(xi) ⱕ u, the likelihood is 1/un, which is positive, but as soon as u ⬍ max(xi), the likelihood drops to 0. This is illustrated in Figure 6.6. Calculus will not work because the maximum of the likelihood occurs at a point of discontinuity, but the figure shows that û 5 max(Xi). Thus if my waiting times are 2.3, 3.7, 1.5, .4, and 3.2, then the mle is û 5 3.7. From Example 6.4, the mle is not unbiased. ■ Example 6.23 A method that is often used to estimate the size of a wildlife population involves performing a capture/recapture experiment. In this experiment, an initial sample of M animals is captured, each of these animals is tagged, and the animals are then returned to the population. After allowing enough time for the tagged individuals to mix into the population, another sample of size n is captured. With X ⫽ the number of tagged animals in the second sample, the objective is to use the observed x to estimate the population size N. The parameter of interest is u ⫽ N, which can assume only integer values, so even after determining the likelihood function (pmf of X here), using calculus to obtain N would present difficulties. If we think of a success as a previously tagged animal being recaptured, then sampling is without replacement from a population containing M successes and N ⫺ M failures, so that X is a hypergeometric rv and the likelihood function is p(x; N ) 5 h(x; n, M, N) 5 M QxR # Q Nn 22 Mx R N Qn R The integer-valued nature of N notwithstanding, it would be difficult to take the derivative of p(x; N). However, if we consider the ratio of p(x; N) to p(x; N ⫺ 1), we have (N 2 M) # (N 2 n) p(x; N ) 5 p(x; N 2 1) N(N 2 M 2 n 1 x) This ratio is larger than 1 if and only if (iff ) N ⬍ Mn/x. The value of N for which p(x; N) is maximized is therefore the largest integer less than Mn/x. If we use standard mathematical notation [r] for the largest integer less than or equal to r, the mle of N is N̂ ⫽ [Mn /x]. As an illustration, if M ⫽ 200 fish are taken from a lake and tagged, and subsequently n ⫽ 100 fish are recaptured, and among the 100 there are x ⫽ 11 tagged fish, then N̂ ⫽ [(200)(100)/11] ⫽ [1818.18] ⫽ 1818. The estimate is actually rather intuitive; x/n is the proportion of the recaptured sample that is tagged, whereas M/N is the proportion of the entire population that is tagged. The estimate is obtained by equating these two proportions (estimating a population proportion by a sample proportion). ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 264 CHAPTER 6 Point Estimation Suppose X1, X2, . . . , Xn is a random sample from a pdf f (x; u) that is symmetric about u but that the investigator is unsure of the form of the f function. It is then desirable to use an estimator û that is robust—that is, one that performs well for a wide variety of underlying pdf’s. One such estimator is a trimmed mean. In recent years, statisticians have proposed another type of estimator, called an M-estimator, based on a generalization of maximum likelihood estimation. Instead of maximizing the log likelihood ⌺ln[ f (x; u )] for a specified f, one maximizes ⌺r(xi; u). The “objective function” r is selected to yield an estimator with good robustness properties. The book by David Hoaglin et al. (see the bibliography) contains a good exposition on this subject. EXERCISES Section 6.2 (20–30) 20. A diagnostic test for a certain disease is applied to n individuals known to not have the disease. Let X ⫽ the number among the n test results that are positive (indicating presence of the disease, so X is the number of false positives) and p ⫽ the probability that a disease-free individual’s test result is positive (i.e., p is the true proportion of test results from disease-free individuals that are positive). Assume that only X is available rather than the actual sequence of test results. a. Derive the maximum likelihood estimator of p. If n ⫽ 20 and x ⫽ 3, what is the estimate? b. Is the estimator of part (a) unbiased? c. If n ⫽ 20 and x ⫽ 3, what is the mle of the probability (1 ⫺ p)5 that none of the next five tests done on diseasefree individuals are positive? 21. Let X have a Weibull distribution with parameters a and b, so E(X) ⫽ b ⭈ ⌫(1 ⫹ 1/a) V(X) ⫽ b2{⌫(1 ⫹ 2/a) ⫺ [⌫(1 ⫹ 1/a)]2} a. Based on a random sample X1, . . . , Xn, write equations for the method of moments estimators of b and a. Show that, once the estimate of a has been obtained, the estimate of b can be found from a table of the gamma function and that the estimate of a is the solution to a complicated equation involving the gamma function. b. If n ⫽ 20, x ⫽ 28.0, and g x 2i 5 16,500, compute the estimates. [Hint: [⌫(1.2)]2/⌫(1.4) ⫽ .95.] 22. Let X denote the proportion of allotted time that a randomly selected student spends working on a certain aptitude test. Suppose the pdf of X is f (x; u) 5 e (u 1 1)x u 0 0#x#1 otherwise where ⫺1 ⬍ u. A random sample of ten students yields data x1 ⫽ .92, x2 ⫽ .79, x3 ⫽ .90, x4 ⫽ .65, x5 ⫽ .86, x6 ⫽ .47, x7 ⫽ .73, x8 ⫽ .97, x9 ⫽ .94, x10 ⫽ .77. a. Use the method of moments to obtain an estimator of u, and then compute the estimate for this data. b. Obtain the maximum likelihood estimator of u, and then compute the estimate for the given data. 23. Two different computer systems are monitored for a total of n weeks. Let Xi denote the number of breakdowns of the first system during the ith week, and suppose the Xi’s are independent and drawn from a Poisson distribution with parameter m1. Similarly, let Yi denote the number of breakdowns of the second system during the ith week, and assume independence with each Yi Poisson with parameter m2. Derive the mle’s of m1, m2, and m1 ⫺ m2. [Hint: Using independence, write the joint pmf (likelihood) of the Xi’s and Yi’s together.] 24. A vehicle with a particular defect in its emission control system is taken to a succession of randomly selected mechanics until r ⫽ 3 of them have correctly diagnosed the problem. Suppose that this requires diagnoses by 20 different mechanics (so there were 17 incorrect diagnoses). Let p ⫽ P(correct diagnosis), so p is the proportion of all mechanics who would correctly diagnose the problem. What is the mle of p? Is it the same as the mle if a random sample of 20 mechanics results in 3 correct diagnoses? Explain. How does the mle compare to the estimate resulting from the use of the unbiased estimator given in Exercise 17? 25. The shear strength of each of ten test spot welds is determined, yielding the following data (psi): 392 376 401 367 389 362 409 415 358 375 a. Assuming that shear strength is normally distributed, estimate the true average shear strength and standard deviation of shear strength using the method of maximum likelihood. b. Again assuming a normal distribution, estimate the strength value below which 95% of all welds will have their strengths. [Hint: What is the 95th percentile in terms of m and s? Now use the invariance principle.] Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Supplementary Exercises 26. Refer to Exercise 25. Suppose we decide to examine another test spot weld. Let X ⫽ shear strength of the weld. Use the given data to obtain the mle of P(X ⱕ 400). [Hint: P(X ⱕ 400) ⫽ ⌽((400 ⫺ m)/s).] 27. Let X1, . . . , Xn be a random sample from a gamma distribution with parameters a and b. a. Derive the equations whose solutions yield the maximum likelihood estimators of a and b. Do you think they can be solved explicitly? b. Show that the mle of m ⫽ ab is m̂ 5 X. 28. Let X1, X2, . . . , Xn represent a random sample from the Rayleigh distribution with density function given in Exercise 15. Determine a. The maximum likelihood estimator of u, and then calculate the estimate for the vibratory stress data given in that exercise. Is this estimator the same as the unbiased estimator suggested in Exercise 15? b. The mle of the median of the vibratory stress distribution. [Hint: First express the median in terms of u.] 29. Consider a random sample X1, X2, . . . , Xn from the shifted exponential pdf f (x; l, u) 5 e le2l(x2u) 0 265 Taking u ⫽ 0 gives the pdf of the exponential distribution considered previously (with positive density to the right of zero). An example of the shifted exponential distribution appeared in Example 4.5, in which the variable of interest was time headway in traffic flow and u ⫽ .5 was the minimum possible time headway. a. Obtain the maximum likelihood estimators of u and l. b. If n ⫽ 10 time headway observations are made, resulting in the values 3.11, .64, 2.55, 2.20, 5.44, 3.42, 10.39, 8.93, 17.82, and 1.30, calculate the estimates of u and l. 30. At time t ⫽ 0, 20 identical components are tested. The lifetime distribution of each is exponential with parameter l. The experimenter then leaves the test facility unmonitored. On his return 24 hours later, the experimenter immediately terminates the test after noticing that y ⫽ 15 of the 20 components are still in operation (so 5 have failed). Derive the mle of l. [Hint: Let Y ⫽ the number that survive 24 hours. Then Y ⬃ Bin(n, p). What is the mle of p? Now notice that p ⫽ P(Xi ⱖ 24), where Xi is exponentially distributed. This relates l to p, so the former can be estimated once the latter has been.] x$u otherwise SUPPLEMENTARY EXERCISES (31–38) 31. An estimator uˆ is said to be consistent if for any P ⬎ 0, P(| û 2 u| $ P) S 0 as n S ` . That is, uˆ is consistent if, as the sample size gets larger, it is less and less likely that uˆ will be further than P from the true value of u. Show that X is a consistent estimator of m when s2 ⬍ ` by using Chebyshev’s inequality from Exercise 44 of Chapter 3. [Hint: The inequality can be rewritten in the form P(|Y 2 mY | $ P) # s2Y /P Now identify Y with X.] 32. a. Let X1, . . . , Xn be a random sample from a uniform distribution on [0, u]. Then the mle of u is uˆ 5 Y 5 max(Xi) . Use the fact that Y ⱕ y iff each Xi ⱕ y to derive the cdf of Y. Then show that the pdf of Y ⫽ max(Xi ) is nyn21 0#y# u fY (y) 5 u un 0 otherwise b. Use the result of part (a) to show that the mle is biased but that (n ⫹ 1)max(Xi)/n is unbiased. 33. At time t ⫽ 0, there is one individual alive in a certain population. A pure birth process then unfolds as follows. The time until the first birth is exponentially distributed with parameter l. After the first birth, there are two individuals alive. The time until the first gives birth again is exponential with parameter l, and similarly for the second individual. Therefore, the time until the next birth is the minimum of two exponential (l) variables, which is exponential with parameter 2l. Similarly, once the second birth has occurred, there are three individuals alive, so the time until the next birth is an exponential rv with parameter 3l, and so on (the memoryless property of the exponential distribution is being used here). Suppose the process is observed until the sixth birth has occurred and the successive birth times are 25.2, 41.7, 51.2, 55.5, 59.5, 61.8 (from which you should calculate the times between successive births). Derive the mle of l. [Hint: The likelihood is a product of exponential terms.] 34. The mean squared error of an estimator uˆ is ˆ 5 E(uˆ 2 u)2. If uˆ is unbiased, then MSE(u) ˆ 5 V(u), ˆ MSE( u) ˆ ˆ 2 but in general MSE(u) 5 V(u ) 1 (bias) . Consider the estimator ŝ2 5 KS 2, where S2 ⫽ sample variance. What value of Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 266 CHAPTER 6 Point Estimation K minimizes the mean squared error of this estimator when the population distribution is normal? [Hint: It can be shown that E[(S 2)2] ⫽ (n ⫹ 1)s4/(n ⫺ 1) ˆ, In general, it is difficult to find û to minimize MSE(u) which is why we look only at unbiased estimators and ˆ .] minimize V(u) 35. Let X1, . . . , Xn be a random sample from a pdf that is symmetric about m. An estimator for m that has been found to perform well for a variety of underlying distributions is the Hodges–Lehmann estimator. To define it, first compute for each i ⱕ j and each j ⫽ 1, 2, . . . , n the pairwise average Xi,j ⫽ (Xi ⫹ Xj)/2. Then the estimator is m̂ ⫽ the median of the Xi,j’s. Compute the value of this estimate using the data of Exercise 44 of Chapter 1. [Hint: Construct a square table with the xi’s listed on the left margin and on top. Then compute averages on and above the diagonal.] 36. When the population distribution is normal, the statistic | median {| X1 ⫺ X |, . . . , | Xn ⫺ | X |}/.6745 can be used to estimate s. This estimator is more resistant to the effects of outliers (observations far from the bulk of the data) than is the sample standard deviation. Compute both the corresponding point estimate and s for the data of Example 6.2. 37. When the sample standard deviation S is based on a random sample from a normal population distribution, it can be shown that E(S) 5 12/(n 2 1)⌫(n/2)s/⌫((n 2 1)/2) Use this to obtain an unbiased estimator for s of the form cS. What is c when n ⫽ 20? 38. Each of n specimens is to be weighed twice on the same scale. Let Xi and Yi denote the two observed weights for the ith specimen. Suppose Xi and Yi are independent of one another, each normally distributed with mean value mi (the true weight of specimen i) and variance s2. a. Show that the maximum likelihood estimator of s2 is ŝ2 5 g(Xi 2 Yi)2/(4n). [Hint: If z ⫽ (z1 ⫹ z2)/2, then ⌺(zi ⫺ z )2 ⫽ (z1 ⫺ z2)2/2.] b. Is the mle ŝ2 an unbiased estimator of s2? Find an unbiased estimator of s2. [Hint: For any rv Z, E(Z 2) ⫽ V(Z) ⫹ [E(Z)]2. Apply this to Z ⫽ Xi ⫺ Yi.] Bibliography DeGroot, Morris, and Mark Schervish, Probability and Statistics (3rd ed.), Addison-Wesley, Boston, MA, 2002. Includes an excellent discussion of both general properties and methods of point estimation; of particular interest are examples showing how general principles and methods can yield unsatisfactory estimators in particular situations. Devore, Jay, and Kenneth Berk, Modern Mathematical Statistics with Applications, Thomson-Brooks/Cole, Belmont, CA, 2007. The exposition is a bit more comprehensive and sophisticated than that of the current book. Efron, Bradley, and Robert Tibshirani, An Introduction to the Bootstrap, Chapman and Hall, New York, 1993. The bible of the bootstrap. Hoaglin, David, Frederick Mosteller, and John Tukey, Understanding Robust and Exploratory Data Analysis, Wiley, New York, 1983. Contains several good chapters on robust point estimation, including one on M-estimation. Rice, John, Mathematical Statistics and Data Analysis (3rd ed.), Thomson-Brooks/Cole, Belmont, CA, 2007. A nice blending of statistical theory and data. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 7 Statistical Intervals Based on a Single Sample INTRODUCTION A point estimate, because it is a single number, by itself provides no information about the precision and reliability of estimation. Consider, for example, using the statistic X to calculate a point estimate for the true average breaking strength (g) of paper towels of a certain brand, and suppose that x 5 9322.7. Because of sampling variability, it is virtually never the case that x 5 m. The point estimate says nothing about how close it might be to m. An alternative to reporting a single sensible value for the parameter being estimated is to calculate and report an entire interval of plausible values—an interval estimate or confidence interval (CI). A confidence interval is always calculated by first selecting a confidence level, which is a measure of the degree of reliability of the interval. A confidence interval with a 95% confidence level for the true average breaking strength might have a lower limit of 9162.5 and an upper limit of 9482.9. Then at the 95% confidence level, any value of m between 9162.5 and 9482.9 is plausible. A confidence level of 95% implies that 95% of all samples would give an interval that includes m, or whatever other parameter is being estimated, and only 5% of all samples would yield an erroneous interval. The most frequently used confidence levels are 95%, 99%, and 90%. The higher the confidence level, the more strongly we believe that the value of the parameter being estimated lies within the interval (an interpretation of any particular confidence level will be given shortly). Information about the precision of an interval estimate is conveyed by the width of the interval. If the confidence level is high and the resulting interval is quite narrow, our knowledge of the value of the parameter is reasonably precise. A very wide confidence interval, however, gives the message that there is 267 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 268 CHAPTER 7 Statistical Intervals Based on a Single Sample a great deal of uncertainty concerning the value of what we are estimating. Figure 7.1 shows 95% confidence intervals for true average breaking strengths of two different brands of paper towels. One of these intervals suggests precise knowledge about m, whereas the other suggests a very wide range of plausible values. ( Brand 1: Brand 2: Figure 7.1 ) ( Strength ) Strength CIs indicating precise (brand 1) and imprecise (brand 2) information about m 7.1 Basic Properties of Confidence Intervals The basic concepts and properties of confidence intervals (CIs) are most easily introduced by first focusing on a simple, albeit somewhat unrealistic, problem situation. Suppose that the parameter of interest is a population mean m and that 1. The population distribution is normal 2. The value of the population standard deviation s is known Normality of the population distribution is often a reasonable assumption. However, if the value of m is unknown, it is typically implausible that the value of s would be available (knowledge of a population’s center typically precedes information concerning spread). We’ll develop methods based on less restrictive assumptions in Sections 7.2 and 7.3. Example 7.1 Industrial engineers who specialize in ergonomics are concerned with designing workspace and worker-operated devices so as to achieve high productivity and comfort. The article “Studies on Ergonomically Designed Alphanumeric Keyboards” (Human Factors, 1985: 175–187) reports on a study of preferred height for an experimental keyboard with large forearm–wrist support. A sample of n 5 31 trained typists was selected, and the preferred keyboard height was determined for each typist. The resulting sample average preferred height was x 5 80.0 cm. Assuming that the preferred height is normally distributed with s 5 2.0 cm (a value suggested by data in the article), obtain a CI for m, the true average preferred height for the population of all experienced typists. ■ The actual sample observations x1, x2, c, xn are assumed to be the result of a random sample X1, c, Xn from a normal distribution with mean value m and standard deviation s. The results described in Chapter 5 then imply that, irrespective of the sample size n, the sample mean X is normally distributed with expected value m and standard deviation s/ 1n. Standardizing X by first subtracting its expected value and then dividing by its standard deviation yields the standard normal variable Z5 X2m s/ 1n (7.1) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 7.1 Basic Properties of Confidence Intervals 269 Because the area under the standard normal curve between 21.96 and 1.96 is .95, X2m , 1.96b 5 .95 s/ 1n Pa21.96 , (7.2) Now let’s manipulate the inequalities inside the parentheses in (7.2) so that they appear in the equivalent form l , m , m, where the endpoints l and u involve X and s/ 1n. This is achieved through the following sequence of operations, each yielding inequalities equivalent to the original ones. 1. Multiply through by s/ 1n: 21.96 # s s , X 2 m , 1.96 # 1n 1n 2. Subtract X from each term: 2X 2 1.96 # s s , 2m , 2X 1 1.96 # 1n 1n 3. Multiply through by 21 to eliminate the minus sign in front of m (which reverses the direction of each inequality): X 1 1.96 # s s . m . X 2 1.96 # 1n 1n X 2 1.96 # s s , m , X 1 1.96 # 1n 1n that is, The equivalence of each set of inequalities to the original set implies that PaX 2 1.96 s s , m , X 1 1.96 b 5 .95 1n 1n (7.3) The event inside the parentheses in (7.3) has a somewhat unfamiliar appearance; previously, the random quantity has appeared in the middle with constants on both ends, as in a # Y # b. In (7.3) the random quantity appears on the two ends, whereas the unknown constant m appears in the middle. To interpret (7.3), think of a random interval having left endpoint X 2 1.96 # s/ 1n and right endpoint X 1 1.96 # s/ 1n. In interval notation, this becomes aX 2 1.96 s , 1n # X 1 1.96 # s b 1n (7.4) The interval (7.4) is random because the two endpoints of the interval involve a random variable. It is centered at the sample mean X and extends 1.96s/ 1n to each side of X. Thus the interval’s width is 2 # (1.96) # s/ 1n, which is not random; only the location of the interval (its midpoint X) is random (Figure 7.2). Now (7.3) can be paraphrased as “the probability is .95 that the random interval (7.4) includes or covers the true value of m.” Before any experiment is performed and any data is gathered, it is quite likely that m will lie inside the interval (7.4). 1.96 / X 1.96 / Figure 7.2 n 1.96 / n X n X 1.96 / n The random interval (7.4) centered at X Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 270 CHAPTER 7 Statistical Intervals Based on a Single Sample DEFINITION If, after observing X1 5 x1, X2 5 x2, c, Xn 5 xn, we compute the observed sample mean x and then substitute x into (7.4) in place of X, the resulting fixed interval is called a 95% confidence interval for M. This CI can be expressed either as ax 2 1.96 # s s , x 1 1.96 # b is a 95% CI for m 1n 1n or as x 2 1.96 # s s , m , x 1 1.96 # with 95% confidence 1n 1n A concise expression for the interval is x 6 1.96 # s/ 1n, where 2 gives the left endpoint (lower limit) and 1 gives the right endpoint (upper limit). Example 7.2 (Example 7.1 continued) The quantities needed for computation of the 95% CI for true average preferred height are s 5 2.0, n 5 31, and x 5 80.0. The resulting interval is x 6 1.96 # s 2.0 5 80.0 6 (1.96) 5 80.0 6 .7 5 (79.3, 80.7) 1n 131 That is, we can be highly confident, at the 95% confidence level, that 79.3 , m , 80.7. This interval is relatively narrow, indicating that m has been rather precisely estimated. ■ Interpreting a Confidence Level The confidence level 95% for the interval just defined was inherited from the probability .95 for the random interval (7.4). Intervals having other levels of confidence will be introduced shortly. For now, though, consider how 95% confidence can be interpreted. Because we started with an event whose probability was .95—that the random interval (7.4) would capture the true value of m—and then used the data in Example 7.1 to compute the CI (79.3, 80.7), it is tempting to conclude that m is within this fixed interval with probability .95. But by substituting x 5 80.0 for X, all randomness disappears; the interval (79.3, 80.7) is not a random interval, and m is a constant (unfortunately unknown to us). It is therefore incorrect to write the statement P(m lies in (79.3, 80.7)) 5 .95. A correct interpretation of “95% confidence” relies on the long-run relative frequency interpretation of probability: To say that an event A has probability .95 is to say that if the experiment on which A is defined is performed over and over again, in the long run A will occur 95% of the time. Suppose we obtain another sample of typists’ preferred heights and compute another 95% interval. Then we consider repeating this for a third sample, a fourth sample, a fifth sample, and so on. Let A be the event that X 2 1.96 # s/ 1n , m , X 1 1.96 # s/ 1n. Since P(A) 5 .95, in the long run 95% of our computed CIs will contain m. This is illustrated in Figure 7.3, where the vertical line cuts the measurement axis at the true (but unknown) value of m. Notice that 7 of the 100 intervals shown fail to contain m. In the long run, only 5% of the intervals so constructed would fail to contain m. According to this interpretation, the confidence level 95% is not so much a statement about any particular interval such as (79.3, 80.7). Instead it pertains to what would happen if a very large number of like intervals were to be constructed Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 7.1 Basic Properties of Confidence Intervals 271 µ µ Figure 7.3 One hundred 95% CIs (asterisks identify intervals that do not include m). using the same CI formula. Although this may seem unsatisfactory, the root of the difficulty lies with our interpretation of probability—it applies to a long sequence of replications of an experiment rather than just a single replication. There is another approach to the construction and interpretation of CIs that uses the notion of subjective probability and Bayes’ theorem, but the technical details are beyond the scope of this text; the book by DeGroot, et al. (see the Chapter 6 bibliography) is a good source. The interval presented here (as well as each interval presented subsequently) is called a “classical” CI because its interpretation rests on the classical notion of probability. Other Levels of Confidence The confidence level of 95% was inherited from the probability .95 for the initial inequalities in (7.2). If a confidence level of 99% is desired, the initial probability of .95 must be replaced by .99, which necessitates changing the z critical value from 1.96 to 2.58. A 99% CI then results from using 2.58 in place of 1.96 in the formula for the 95% CI. In fact, any desired level of confidence can be achieved by replacing 1.96 or 2.58 with the appropriate standard normal critical value. As Figure 7.4 shows, a probability of 1 2 a is achieved by using za/2 in place of 1.96. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 272 CHAPTER 7 Statistical Intervals Based on a Single Sample z curve 1 z/2 Figure 7.4 DEFINITION 0 Shaded area /2 z /2 P(2za/2 # Z , za/2) 5 1 2 a A 100(1 2 a)% confidence interval for the mean m of a normal population when the value of s is known is given by ax 2 za/2 # s s , x 1 za/2 # b 1n 1n (7.5) or, equivalently, by x 6 za/2 # s/ 1n. The formula (7.5) for the CI can also be expressed in words as point estimate of m 6 (z critical value) (standard error of the mean). Example 7.3 The production process for engine control housing units of a particular type has recently been modified. Prior to this modification, historical data had suggested that the distribution of hole diameters for bushings on the housings was normal with a standard deviation of .100 mm. It is believed that the modification has not affected the shape of the distribution or the standard deviation, but that the value of the mean diameter may have changed. A sample of 40 housing units is selected and hole diameter is determined for each one, resulting in a sample mean diameter of 5.426 mm. Let’s calculate a confidence interval for true average hole diameter using a confidence level of 90%. This requires that 100(1 2 a) 5 90, from which a 5 .10 and za/2 5 z.05 5 1.645 (corresponding to a cumulative z-curve area of .9500). The desired interval is then 5.426 6 (1.645) .100 5 5.426 6 .026 5 (5.400, 5.452) 140 With a reasonably high degree of confidence, we can say that 5.400 , m , 5.452. This interval is rather narrow because of the small amount of variability in hole diameter (s 5 .100) . ■ Confidence Level, Precision, and Sample Size Why settle for a confidence level of 95% when a level of 99% is achievable? Because the price paid for the higher confidence level is a wider interval. Since the 95% interval extends 1.96 # s/ 1n to each side of x, the width of the interval is 2(1.96) # s/ 1n 5 3.92 # s/ 1n. Similarly, the width of the 99% interval is 2(2.58) # s/ 1n 5 5.16 # s/ 1n. That is, we have more confidence in the 99% interval precisely because it is wider. The higher the desired degree of confidence, the wider the resulting interval will be. If we think of the width of the interval as specifying its precision or accuracy, then the confidence level (or reliability) of the interval is inversely related to its Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 7.1 Basic Properties of Confidence Intervals 273 precision. A highly reliable interval estimate may be imprecise in that the endpoints of the interval may be far apart, whereas a precise interval may entail relatively low reliability. Thus it cannot be said unequivocally that a 99% interval is to be preferred to a 95% interval; the gain in reliability entails a loss in precision. An appealing strategy is to specify both the desired confidence level and interval width and then determine the necessary sample size. Example 7.4 Extensive monitoring of a computer time-sharing system has suggested that response time to a particular editing command is normally distributed with standard deviation 25 millisec. A new operating system has been installed, and we wish to estimate the true average response time m for the new environment. Assuming that response times are still normally distributed with s 5 25, what sample size is necessary to ensure that the resulting 95% CI has a width of (at most) 10? The sample size n must satisfy 10 5 2 # (1.96)(25/ 1n ) Rearranging this equation gives 1n 5 2 # (1.96)(25)/10 5 9.80 so n 5 (9.80)2 5 96.04 Since n must be an integer, a sample size of 97 is required. ■ A general formula for the sample size n necessary to ensure an interval width w is obtained from equating w to 2 # za/2 # s/ 1n and solving for n. The sample size necessary for the CI (7.5) to have a width w is n 5 a2za/2 # s 2 b w The smaller the desired width w, the larger n must be. In addition, n is an increasing function of s (more population variability necessitates a larger sample size) and of the confidence level 100(1 2 a) (as a decreases, za/2 increases). The half-width 1.96s/ 1n of the 95% CI is sometimes called the bound on the error of estimation associated with a 95% confidence level. That is, with 95% confidence, the point estimate x will be no farther than this from m. Before obtaining data, an investigator may wish to determine a sample size for which a particular value of the bound is achieved. For example, with m representing the average fuel efficiency (mpg) for all cars of a certain type, the objective of an investigation may be to estimate m to within 1 mpg with 95% confidence. More generally, if we wish to estimate m to within an amount B (the specified bound on the error of estimation) with 100(1 2 a) % confidence, the necessary sample size results from replacing 2/w by 1/B in the formula in the preceding box. Deriving a Confidence Interval Let X1, X2, c, Xn denote the sample on which the CI for a parameter u is to be based. Suppose a random variable satisfying the following two properties can be found: Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 274 CHAPTER 7 Statistical Intervals Based on a Single Sample 1. The variable depends functionally on both X1, c, Xn and u. 2. The probability distribution of the variable does not depend on u or on any other unknown parameters. Let h(X1, X2, c, Xn; u) denote this random variable. For example, if the population distribution is normal with known s and u 5 m, the variable h(X1, c, Xn; m) 5 (X 2 m)/(s/ 1n) satisfies both properties; it clearly depends functionally on m, yet has the standard normal probability distribution, which does not depend on m. In general, the form of the h function is usually suggested by examining the distribution of an appropriate estimator û. For any a between 0 and 1, constants a and b can be found to satisfy P(a , h(X1, c, Xn; u) , b) 5 1 2 a (7.6) Because of the second property, a and b do not depend on u. In the normal example, a 5 2za/2 and b 5 za/2. Now suppose that the inequalities in (7.6) can be manipulated to isolate u, giving the equivalent probability statement P(l(X1, X2, c, Xn) , u , u(X1, X2, c, Xn)) 5 1 2 a Then l(x1, x2, c, xn) and u(x1, c, xn) are the lower and upper confidence limits, respectively, for a 100(1 2 a)% CI. In the normal example, we saw that l(X1, c, Xn) 5 X 2 za/2 # s/ 1n and u(X1, c, Xn) 5 X 1 za/2 # s/ 1n. Example 7.5 A theoretical model suggests that the time to breakdown of an insulating fluid between electrodes at a particular voltage has an exponential distribution with parameter l (see Section 4.4). A random sample of n 5 10 breakdown times yields the following sample data (in min): x1 5 41.53, x2 5 18.73, x3 5 2.99, x4 5 30.34, x5 5 12.33, x6 5 117.52, x7 5 73.02, x8 5 223.63, x9 5 4.00, x10 5 26.78. A 95% CI for l and for the true average breakdown time are desired. Let h(X1, X2, c, Xn; l) 5 2lgXi. It can be shown that this random variable has a probability distribution called a chi-squared distribution with 2n degrees of freedom (df) (n 5 2n, where n is the parameter of a chi-squared distribution as mentioned in Section 4.4). Appendix Table A.7 pictures a typical chi-squared density curve and tabulates critical values that capture specified tail areas. The relevant number of df here is 2(10) 5 20. The n 5 20 row of the table shows that 34.170 captures upper-tail area .025 and 9.591 captures lower-tail area .025 (upper-tail area .975). Thus for n 5 10, P(9.591 , 2l g Xi , 34.170) 5 .95 Division by 2g Xi isolates l, yielding P(9.591/(2 g Xi) , l , (34.170/(2 g Xi)) 5 .95 The lower limit of the 95% CI for l is 9.591/(2gxi), and the upper limit is 34.170/(2g xi). For the given data, gxi 5 550.87, giving the interval (.00871, .03101). The expected value of an exponential rv is m 5 1/l. Since P(2 g Xi /34.170 , 1/l , 2 g Xi /9.591) 5 .95 the 95% CI for true average breakdown time is (2gxi /34.170, 2gxi /9.591) 5 (32.24, 114.87). This interval is obviously quite wide, reflecting substantial variability in breakdown times and a small sample size. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 7.1 Basic Properties of Confidence Intervals 275 In general, the upper and lower confidence limits result from replacing each , in (7.6) by and solving for u. In the insulating fluid example just considered, 2lg xi 5 34.170 gives l 5 34.170/(2gxi) as the upper confidence limit, and the lower limit is obtained from the other equation. Notice that the two interval limits are not equidistant from the point estimate, since the interval is not of the form û 6 c. Bootstrap Confidence Intervals The bootstrap technique was introduced in Chapter 6 as a way of estimating sû . It can also be applied to obtain a CI for u. Consider again estimating the mean m of a normal distribution when s is known. Let’s replace m by u and use û 5 X as the point estimator. Notice that 1.96s 1n is the 97.5th percentile of the distribution of û 2 u [that is, P(X 2 m , 1.96s/ 1n) 5 P(Z , 1.96) 5 .9750]. Similarly, 21.96s/ 1n is the 2.5th percentile, so .95 5 P(2.5th percentile , û 2 u , 97.5th percentile) 5 P(û 2 2.5th percentile . u . û 2 97.5th percentile) That is, with l 5 û 2 97.5th percentile of û 2 u u 5 û 2 2.5th percentile of û 2 u (7.7) the CI for u is (l, u). In many cases, the percentiles in (7.7) cannot be calculated, but they can be estimated from bootstrap samples. Suppose we obtain B 5 1000 bootstrap samples and calculate û*1, c, û*1000, and u# * followed by the 1000 differences û*1 2 u# *, c, û*1000 2 u# *. The 25th largest and 25th smallest of these differences are estimates of the unknown percentiles in (7.7). Consult the Devore and Berk or Efron books cited in Chapter 6 for more information. EXERCISES Section 7.1 (1–11) 1. Consider a normal population distribution with the value of s known. a. What is the confidence level for the interval x 6 2.81s/ 1n? b. What is the confidence level for the interval x 6 1.44s/ 1n? c. What value of za/2 in the CI formula (7.5) results in a confidence level of 99.7%? d. Answer the question posed in part (c) for a confidence level of 75%. 2. Each of the following is a confidence interval for m true average (i.e., population mean) resonance frequency (Hz) for all tennis rackets of a certain type: (114.4, 115.6) (114.1, 115.9) a. What is the value of the sample mean resonance frequency? b. Both intervals were calculated from the same sample data. The confidence level for one of these intervals is 90% and for the other is 99%. Which of the intervals has the 90% confidence level, and why? 3. Suppose that a random sample of 50 bottles of a particular brand of cough syrup is selected and the alcohol content of each bottle is determined. Let m denote the average alcohol content for the population of all bottles of the brand under study. Suppose that the resulting 95% confidence interval is (7.8, 9.4). a. Would a 90% confidence interval calculated from this same sample have been narrower or wider than the given interval? Explain your reasoning. b. Consider the following statement: There is a 95% chance that m is between 7.8 and 9.4. Is this statement correct? Why or why not? c. Consider the following statement: We can be highly confident that 95% of all bottles of this type of cough syrup have an alcohol content that is between 7.8 and 9.4. Is this statement correct? Why or why not? d. Consider the following statement: If the process of selecting a sample of size 50 and then computing the corresponding 95% interval is repeated 100 times, 95 of the resulting intervals will include m. Is this statement correct? Why or why not? Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 276 CHAPTER 7 Statistical Intervals Based on a Single Sample 4. A CI is desired for the true average stray-load loss m (watts) for a certain type of induction motor when the line current is held at 10 amps for a speed of 1500 rpm. Assume that strayload loss is normally distributed with s 5 3.0. a. Compute a 95% CI for m when n 5 25 and x 5 58.3. b. Compute a 95% CI for m when n 5 100 and x 5 58.3. c. Compute a 99% CI for m when n 5 100 and x 5 58.3. d. Compute an 82% CI for m when n 5 100 and x 5 58.3. e. How large must n be if the width of the 99% interval for m is to be 1.0? 5. Assume that the helium porosity (in percentage) of coal samples taken from any particular seam is normally distributed with true standard deviation .75. a. Compute a 95% CI for the true average porosity of a certain seam if the average porosity for 20 specimens from the seam was 4.85. b. Compute a 98% CI for true average porosity of another seam based on 16 specimens with a sample average porosity of 4.56. c. How large a sample size is necessary if the width of the 95% interval is to be .40? d. What sample size is necessary to estimate true average porosity to within .2 with 99% confidence? 6. On the basis of extensive tests, the yield point of a particular type of mild steel-reinforcing bar is known to be normally distributed with s 5 100. The composition of bars has been slightly modified, but the modification is not believed to have affected either the normality or the value of s. a. Assuming this to be the case, if a sample of 25 modified bars resulted in a sample average yield point of 8439 lb, compute a 90% CI for the true average yield point of the modified bar. b. How would you modify the interval in part (a) to obtain a confidence level of 92%? 7. By how much must the sample size n be increased if the width of the CI (7.5) is to be halved? If the sample size is increased by a factor of 25, what effect will this have on the width of the interval? Justify your assertions. 8. Let a1 . 0, a2 . 0, with a1 1 a2 5 a. Then Pa2za1 , X2m , za2 b 5 1 2 a s/ 1n a. Use this equation to derive a more general expression for a 100(1 2 a)% CI for m of which the interval (7.5) is a special case. b. Let a 5 .05 and a1 5 a/4, a2 5 3a/4. Does this result in a narrower or wider interval than the interval (7.5)? 9. a. Under the same conditions as those leading to the interval (7.5), P[(X 2 m)/(s/ 1n) , 1.645] 5 .95. Use this to derive a one-sided interval for m that has infinite width and provides a lower confidence bound on m. What is this interval for the data in Exercise 5(a)? b. Generalize the result of part (a) to obtain a lower bound with confidence level 100(1 2 a)%. c. What is an analogous interval to that of part (b) that provides an upper bound on m? Compute this 99% interval for the data of Exercise 4(a). 10. A random sample of n 5 15 heat pumps of a certain type yielded the following observations on lifetime (in years): 2.0 1.3 6.0 1.9 5.1 .4 1.0 15.7 .7 4.8 .9 12.2 5.3 .6 5.3 a. Assume that the lifetime distribution is exponential and use an argument parallel to that of Example 7.5 to obtain a 95% CI for expected (true average) lifetime. b. How should the interval of part (a) be altered to achieve a confidence level of 99%? c. What is a 95% CI for the standard deviation of the lifetime distribution? [Hint: What is the standard deviation of an exponential random variable?] 11. Consider the next 1000 95% CIs for m that a statistical consultant will obtain for various clients. Suppose the data sets on which the intervals are based are selected independently of one another. How many of these 1000 intervals do you expect to capture the corresponding value of m? What is the probability that between 940 and 960 of these intervals contain the corresponding value of m? [Hint: Let Y the number among the 1000 intervals that contain m. What kind of random variable is Y?] 7.2 Large-Sample Confidence Intervals for a Population Mean and Proportion The CI for m given in the previous section assumed that the population distribution is normal with the value of s known. We now present a large-sample CI whose validity does not require these assumptions. After showing how the argument leading to this interval generalizes to yield other large-sample intervals, we focus on an interval for a population proportion p. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 7.2 Large-Sample Confidence Intervals for a Population Mean and Proportion 277 A Large-Sample Interval for m Let X1, X2, c, Xn be a random sample from a population having a mean m and standard deviation s. Provided that n is large, the Central Limit Theorem (CLT) implies that X has approximately a normal distribution whatever the nature of the population distribution. It then follows that Z 5 (X 2 m)/(s/ 1n) has approximately a standard normal distribution, so that Pa2za/2 , X2m , za/2 b < 1 2 a s/ 1n An argument parallel to that given in Section 7.1 yields x 6 za/2 # s/ 1n as a largesample CI for m with a confidence level of approximately 100(1 2 a)%. That is, when n is large, the CI for m given previously remains valid whatever the population distribution, provided that the qualifier “approximately” is inserted in front of the confidence level. A practical difficulty with this development is that computation of the CI requires the value of s, which will rarely be known. Consider the standardized variable (X 2 m)/(S/ 1n), in which the sample standard deviation S has replaced s. Previously, there was randomness only in the numerator of Z by virtue of X. In the new standardized variable, both X and S vary in value from one sample to another. So it might seem that the distribution of the new variable should be more spread out than the z curve to reflect the extra variation in the denominator. This is indeed true when n is small. However, for large n the subsititution of S for s adds little extra variability, so this variable also has approximately a standard normal distribution. Manipulation of the variable in a probability statement, as in the case of known s, gives a general large-sample CI for m. PROPOSITION If n is sufficiently large, the standardized variable Z5 X2m S/ 1n has approximately a standard normal distribution. This implies that x 6 za/2 # s 1n (7.8) is a large-sample confidence interval for ␮ with confidence level approximately 100(1 2 a)%. This formula is valid regardless of the shape of the population distribution. In words, the CI (7.8) is point estimate of m 6 (z critical value) (estimated standard error of the mean). Generally speaking, n . 40 will be sufficient to justify the use of this interval. This is somewhat more conservative than the rule of thumb for the CLT because of the additional variability introduced by using S in place of s. Example 7.6 Haven’t you always wanted to own a Porsche? The author thought maybe he could afford a Boxster, the cheapest model. So he went to www.cars.com on Nov. 18, 2009, and found a total of 1113 such cars listed. Asking prices ranged from $3499 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 278 CHAPTER 7 Statistical Intervals Based on a Single Sample to $130,000 (the latter price was one of only two exceeding $70,000). The prices depressed him, so he focused instead on odometer readings (miles). Here are reported readings for a sample of 50 of these Boxsters: 2948 2996 15767 20000 35700 36466 45000 45027 54208 56062 64404 72140 113000 118634 7197 23247 40316 45442 57000 74594 8338 24863 40596 46963 57365 79308 8500 26000 41021 47978 60020 79500 8759 26210 41234 49518 60265 80000 12710 30552 43000 52000 60803 80000 12925 30600 44607 53334 62851 84000 A boxplot of the data (Figure 7.5) shows that, except for the two outliers at the upper end, the distribution of values is reasonably symmetric (in fact, a normal probability plot exhibits a reasonably linear pattern, though the points corresponding to the two smallest and two largest observations are somewhat removed from a line fit through the remaining points). Mileage 0 20000 Figure 7.5 40000 60000 80000 100000 120000 A boxplot of the odometer reading data from Example 7.6 Summary quantities include n 5 50, x 5 45,679.4, | x 5 45,013.5, s 5 26,641.675, fs 5 34,265. The mean and median are reasonably close (if the two largest values were each reduced by 30,000, the mean would fall to 44,479.4, while the median would be unaffected). The boxplot and the magnitudes of s and fs relative to the mean and median both indicate a substantial amount of variability. A confidence level of about 95% requires z.025 5 1.96, and the interval is 26,641.675 b 5 45,679.4 6 7384.7 150 5 (38,294.7, 53,064.1) 45,679.4 6 (1.96)a That is, 38, 294.7 , m , 53,064.1 with 95% confidence. This interval is rather wide because a sample size of 50, even though large by our rule of thumb, is not large enough to overcome the substantial variability in the sample. We do not have a very precise estimate of the population mean odometer reading. Is the interval we’ve calculated one of the 95% that in the long run includes the parameter being estimated, or is it one of the “bad” 5% that does not do so? Without knowing the value of m, we cannot tell. Remember that the confidence level refers to the long run capture percentage when the formula is used repeatedly on various samples; it cannot be interpreted for a single sample and the resulting interval. ■ Unfortunately, the choice of sample size to yield a desired interval width is not as straightforward here as it was for the case of known s. This is because the width Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 7.2 Large-Sample Confidence Intervals for a Population Mean and Proportion 279 of (7.8) is 2za/2s/ 1n. Since the value of s is not available before the data has been gathered, the width of the interval cannot be determined solely by the choice of n. The only option for an investigator who wishes to specify a desired width is to make an educated guess as to what the value of s might be. By being conservative and guessing a larger value of s, an n larger than necessary will be chosen. The investigator may be able to specify a reasonably accurate value of the population range (the difference between the largest and smallest values). Then if the population distribution is not too skewed, dividing the range by 4 gives a ballpark value of what s might be. Example 7.7 The charge-to-tap time (min) for carbon steel in one type of open hearth furnace is to be determined for each heat in a sample of size n. If the investigator believes that almost all times in the distribution are between 320 and 440, what sample size would be appropriate for estimating the true average time to within 5 min. with a confidence level of 95%? A reasonable value for s is (440 2 320)/4 5 30. Thus n5 c (1.96)(30) 2 d 5 138.3 5 Since the sample size must be an integer, n 5 139 should be used. Note that estimating to within 5 min. with the specified confidence level is equivalent to a CI width of 10 min. ■ A General Large-Sample Confidence Interval The large-sample intervals x 6 za/2 # s/ 1n and x 6 za/2 # s/ 1n are special cases of a general large-sample CI for a parameter u. Suppose that û is an estimator satisfying the following properties: (1) It has approximately a normal distribution; (2) it is (at least approximately) unbiased; and (3) an expression for sû , the standard deviation of û, is available. For example, in the case u 5 m, m̂ 5 X is an unbiased estimator whose distribution is approximately normal when n is large and sm̂ 5 sX 5 s/2n. Standardizing û yields the rv Z 5 (û 2 u)/sû , which has approximately a standard normal distribution. This justifies the probability statement Pa2za/2 , û 2 u , za/2 b < 1 2 a sû (7.9) Suppose first that sû does not involve any unknown parameters (e.g., known s in the case u 5 m). Then replacing each , in (7.9) by 5 results in u 5 û 6 za/2 # sû , so the lower and upper confidence limits are û 2 za/2 # sû and û 1 za/2 # sû , respectively. Now suppose that sû does not involve u but does involve at least one other unknown parameter. Let sû be the estimate of sû obtained by using estimates in place of the unknown parameters (e.g., s/ 1n estimates s/ 1n). Under general conditions (essentially that sû be close to sû for most samples), a valid CI is û 6 za/2 # sû . The large-sample interval x 6 za/2 # s/ 1n is an example. Finally, suppose that sû does involve the unknown u. This is the case, for example, when u 5 p, a population proportion. Then (û 2 u)/sû 5 za/2 can be difficult to solve. An approximate solution can often be obtained by replacing u in sû by its estimate û. This results in an estimated standard deviation sû , and the corresponding interval is again û 6 za/2 # sû. In words, this CI is a point estimate of u 6 (z critical value)(estimated standard error of the estimator) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 280 CHAPTER 7 Statistical Intervals Based on a Single Sample A Confidence Interval for a Population Proportion Let p denote the proportion of “successes” in a population, where success identifies an individual or object that has a specified property (e.g., individuals who graduated from college, computers that do not need warranty service, etc.). A random sample of n individuals is to be selected, and X is the number of successes in the sample. Provided that n is small compared to the population size, X can be regarded as a binomial rv with E(X) 5 np and sX 5 #np(1 2 p). Furthermore, if both np $ 10 and nq $ 10, (q 5 1 2 p), X has approximately a normal distribution. The natural estimator of p is p̂ 5 X/n, the sample fraction of successes. Since p̂ is just X multiplied by the constant 1/n, p̂ also has approximately a normal distribution. As shown in Section 6.1, E(p̂) 5 p (unbiasedness) and sp̂ 5 #p(1 2 p)/n. The standard deviation sp̂ involves the unknown parameter p. Standardizing p̂ by subtracting p and dividing by sp̂ then implies that , za/2 b < 1 2 a #p(1 2 p)/n Proceeding as suggested in the subsection “Deriving a Confidence Interval” (Section 7.1), the confidence limits result from replacing each , by and solving the resulting quadratic equation for p. This gives the two roots Pa2za/2 , p5 p̂ 2 p p̂ 1 z2a/2 / 2n $p̂(1 2 p̂) / n 1 z2a/2 / 4n2 6 za/2 2 1 1 za/2/n 1 1 z2a/2 / n $p̂(1 2 p̂) / n 1 z2a/2 / 4n2 5| p 6 za/2 1 1 z2a/2 / n PROPOSITION p̂ 1 z2a/2 / 2n . Then a confidence interval for a population propor1 1 z2a/2 / n tion p with confidence level approximately 100(1 2 a)% is p5 Let | $p̂q̂ / n 1 z2a/2 / 4n2 | p 6 za/2 1 1 z2a/2 / n (7.10) where q̂ 5 1 2 p̂ and, as before, the 2 in (7.10) corresponds to the lower confidence limit and the 1 to the upper confidence limit. This is often referred to as the score CI for p. If the sample size n is very large, then z2/2n is generally quite negligible (small) compared to p̂ and z2/n is quite negligible compared to 1, from which | p < p̂. In this case 2 z2/4n2 is also negligible compared to pq/n ( n is a much larger divisor than is n); as ˆˆ a result, the dominant term in the 6 expression is za/2 #p̂q̂/n and the score interval is approximately p̂ 6 za/2 #p̂q̂/n (7.11) This latter interval has the general form û 6 za/2ŝû of a large-sample interval suggested in the last subsection. The approximate CI (7.11) is the one that for decades Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 281 7.2 Large-Sample Confidence Intervals for a Population Mean and Proportion has appeared in introductory statistics textbooks. It clearly has a much simpler and more appealing form than the score CI. So why bother with the latter? First of all, suppose we use z.025 5 1.96 in the traditional formula (7.11). Then our nominal confidence level (the one we think we’re buying by using that z critical value) is approximately 95%. So before a sample is selected, the probability that the random interval includes the actual value of p (i.e., the coverage probability) should be about .95. But as Figure 7.6 shows for the case n 5 100, the actual coverage probability for this interval can differ considerably from the nominal probability .95, particularly when p is not close to .5 (the graph of coverage probability versus p is very jagged because the underlying binomial probability distribution is discrete rather than continuous). This is generally speaking a deficiency of the traditional interval—the actual confidence level can be quite different from the nominal level even for reasonably large sample sizes. Recent research has shown that the score interval rectifies this behavior—for virtually all sample sizes and values of p, its actual confidence level will be quite close to the nominal level specified by the choice of za/2. This is due largely to the fact that the score interval is shifted a bit toward .5 compared to the traditional interval. In particular, the midpoint | p of the score interval is always a bit closer to .5 than is the midpoint p̂ of the traditional interval. This is especially important when p is close to 0 or 1. Coverage probability 0.96 0.94 0.92 0.90 0.88 0.86 p 0 Figure 7.6 0.2 0.4 0.6 0.8 1 Actual coverage probability for the interval (7.11) for varying values of p when n 5 100 In addition, the score interval can be used with nearly all sample sizes and parameter values. It is thus not necessary to check the conditions n p̂ $ 10 and n(1 2 p̂) $ 10 that would be required were the traditional interval employed. So rather than asking when n is large enough for (7.11) to yield a good approximation to (7.10), our recommendation is that the score CI should always be used. The slight additional tediousness of the computation is outweighed by the desirable properties of the interval. Example 7.8 The article “Repeatability and Reproducibility for Pass/Fail Data” (J. of Testing and Eval., 1997: 151–153) reported that in n 5 48 trials in a particular laboratory, 16 resulted in ignition of a particular type of substrate by a lighted cigarette. Let p denote the long-run proportion of all such trials that would result in ignition. A point estimate for p is p̂ 5 16/48 5 .333. A confidence interval for p with a confidence level of approximately 95% is Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 282 CHAPTER 7 Statistical Intervals Based on a Single Sample .333 1 (1.96)2/96 #(.333)(.667)/48 1 (1.96)2/9216 6 (1.96) 2 1 1 (1.96) /48 1 1 (1.96)2/48 5 .345 6 .129 5 (.216, .474) This interval is quite wide because a sample size of 48 is not at all large when estimating a proportion. The traditional interval is .333 6 1.96#(.333)(.667)/48 5 .333 6 .133 5 (.200, .466) These two intervals would be in much closer agreement were the sample size substantially larger. ■ Equating the width of the CI for p to a prespecified width w gives a quadratic equation for the sample size n necessary to give an interval with a desired degree of precision. Suppressing the subscript in za/2, the solution is n5 2z 2p̂q̂ 2 z2w2 6 #4z 4p̂q̂(p̂q̂ 2 w2) 1 w 2z 4 w2 (7.12) Neglecting the terms in the numerator involving w2 gives n< 4z2p̂q̂ w2 This latter expression is what results from equating the width of the traditional interval to w. These formulas unfortunately involve the unknown p̂. The most conservative approach is to take advantage of the fact that p̂q̂[5 p̂(1 2 p̂)] is a maximum when p̂ 5 .5. Thus if p̂ 5 q̂ 5 .5 is used in (7.12), the width will be at most w regardless of what value of p̂ results from the sample. Alternatively, if the investigator believes strongly, based on prior information, that p # p0 # .5, then p0 can be used in place of p̂. A similar comment applies when p $ p0 $ .5. Example 7.9 n5 The width of the 95% CI in Example 7.8 is .258. The value of n necessary to ensure a width of .10 irrespective of the value of p̂ is 2(1.96)2(.25) 2 (1.96)2(.01) 6 #4(1.96)4(.25)(.25 2 .01) 1 (.01)(1.96)4 5 380.3 .01 Thus a sample size of 381 should be used. The expression for n based on the traditional CI gives a slightly larger value of 385. ■ One-Sided Confidence Intervals (Confidence Bounds) The confidence intervals discussed thus far give both a lower confidence bound and an upper confidence bound for the parameter being estimated. In some circumstances, an investigator will want only one of these two types of bounds. For example, a psychologist may wish to calculate a 95% upper confidence bound for true average reaction time to a particular stimulus, or a reliability engineer may want only a lower confidence bound for true average lifetime of components of a certain type. Because the cumulative area under the standard normal curve to the left of 1.645 is .95, Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 7.2 Large-Sample Confidence Intervals for a Population Mean and Proportion Pa 283 X2m , 1.645b < .95 S/ 1n Manipulating the inequality inside the parentheses to isolate m on one side and replacing rv’s by calculated values gives the inequality m . x 2 1.645s/ 1n; the expression on the right is the desired lower confidence bound. Starting with P(21.645 , Z) < .95 and manipulating the inequality results in the upper confidence bound. A similar argument gives a one-sided bound associated with any other confidence level. PROPOSITION A large-sample upper confidence bound for ␮ is m , x 1 za # s 1n and a large-sample lower confidence bound for ␮ is m . x 2 za # s 1n A one-sided confidence bound for p results from replacing za/2 by za and 6 by either 1 or 2 in the CI formula (7.10) for p. In all cases the confidence level is approximately 100(1 2 a)%. Example 7.10 The slant shear test is the most widely accepted procedure for assessing the quality of a bond between a repair material and its concrete substrate. The article “Testing the Bond Between Repair Materials and Concrete Substrate” (ACI Materials J., 1996: 553–558) reported that in one particular investigation, a sample of 48 shear strength observations gave a sample mean strength of 17.17 N/mm2 and a sample standard deviation of 3.28 N/mm2. A lower confidence bound for true average shear strength m with confidence level 95% is 17.17 2 (1.645) (3.28) 5 17.17 2 .78 5 16.39 148 That is, with a confidence level of 95%, we can say that m . 16.39. EXERCISES ■ Section 7.2 (12–27) 12. A random sample of 110 lightning flashes in a certain region resulted in a sample average radar echo duration of .81 sec and a sample standard deviation of .34 sec (“Lightning Strikes to an Airplane in a Thunderstorm,” J. of Aircraft, 1984: 607–611). Calculate a 99% (two-sided) confidence interval for the true average echo duration m, and interpret the resulting interval. 13. The article “Gas Cooking, Kitchen Ventilation, and Exposure to Combustion Products” (Indoor Air, 2006: 65–73) reported that for a sample of 50 kitchens with gas cooking appliances monitored during a one-week period, the sample mean CO2 level (ppm) was 654.16, and the sample standard deviation was 164.43. a. Calculate and interpret a 95% (two-sided) confidence interval for true average CO2 level in the population of all homes from which the sample was selected. b. Suppose the investigators had made a rough guess of 175 for the value of s before collecting data. What sample size would be necessary to obtain an interval width of 50 ppm for a confidence level of 95%? 14. The article “Evaluating Tunnel Kiln Performance” (Amer. Ceramic Soc. Bull., Aug. 1997: 59–63) gave the following Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 284 CHAPTER 7 Statistical Intervals Based on a Single Sample summary information for fracture strengths (MPa) of n 5 169 ceramic bars fired in a particular kiln: x 5 89.10, s 5 3.73. a. Calculate a (two-sided) confidence interval for true average fracture strength using a confidence level of 95%. Does it appear that true average fracture strength has been precisely estimated? b. Suppose the investigators had believed a priori that the population standard deviation was about 4 MPa. Based on this supposition, how large a sample would have been required to estimate m to within .5 MPa with 95% confidence? 15. Determine the confidence level for each of the following large-sample one-sided confidence bounds: a. Upper bound: x 1 .84s/ 1n b. Lower bound: x 2 2.05s/ 1n c. Upper bound: x 1 .67s/ 1n 16. The alternating current (AC) breakdown voltage of an insulating liquid indicates its dielectric strength. The article “Testing Practices for the AC Breakdown Voltage Testing of Insulation Liquids” (IEEE Electrical Insulation Magazine, 1995: 21–26) gave the accompanying sample observations on breakdown voltage (kV) of a particular circuit under certain conditions. 62 50 53 57 41 53 55 61 59 64 50 53 64 62 50 68 54 55 57 50 55 50 56 55 46 55 53 54 52 47 47 55 57 48 63 57 57 55 53 59 53 52 50 55 60 50 56 58 a. Construct a boxplot of the data and comment on interesting features. b. Calculate and interpret a 95% CI for true average breakdown voltage m. Does it appear that m has been precisely estimated? Explain. c. Suppose the investigator believes that virtually all values of breakdown voltage are between 40 and 70. What sample size would be appropriate for the 95% CI to have a width of 2 kV (so that m is estimated to within 1 kV with 95% confidence)? 17. Exercise 1.13 gave a sample of ultimate tensile strength observations (ksi). Use the accompanying descriptive statistics output from Minitab to calculate a 99% lower confidence bound for true average ultimate tensile strength, and interpret the result. N Mean Median TrMean StDev 153 135.39 135.40 135.41 4.59 Minimum Maximum Q1 Q3 122.20 147.70 132.95 138.25 SE Mean 0.37 18. The article “Ultimate Load Capacities of Expansion Anchor Bolts” (J. of Energy Engr., 1993: 139–158) gave the following summary data on shear strength (kip) for a sample of 3/8-in. anchor bolts: n 5 78, x 5 4.25, s 5 1.30. Calculate a lower confidence bound using a confidence level of 90% for true average shear strength. 19. The article “Limited Yield Estimation for Visual Defect Sources” (IEEE Trans. on Semiconductor Manuf., 1997: 17–23) reported that, in a study of a particular wafer inspection process, 356 dies were examined by an inspection probe and 201 of these passed the probe. Assuming a stable process, calculate a 95% (two-sided) confidence interval for the proportion of all dies that pass the probe. 20. The Associated Press (October 9, 2002) reported that in a survey of 4722 American youngsters aged 6 to 19, 15% were seriously overweight (a body mass index of at least 30; this index is a measure of weight relative to height). Calculate and interpret a confidence interval using a 99% confidence level for the proportion of all American youngsters who are seriously overweight. 21. In a sample of 1000 randomly selected consumers who had opportunities to send in a rebate claim form after purchasing a product, 250 of these people said they never did so (“Rebates: Get What You Deserve,” Consumer Reports, May 2009: 7). Reasons cited for their behavior included too many steps in the process, amount too small, missed deadline, fear of being placed on a mailing list, lost receipt, and doubts about receiving the money. Calculate an upper confidence bound at the 95% confidence level for the true proportion of such consumers who never apply for a rebate. Based on this bound, is there compelling evidence that the true proportion of such consumers is smaller than 1/3? Explain your reasoning. 22. The technology underlying hip replacements has changed as these operations have become more popular (over 250,000 in the United States in 2008). Starting in 2003, highly durable ceramic hips were marketed. Unfortunately, for too many patients the increased durability has been counterbalanced by an increased incidence of squeaking. The May 11, 2008, issue of the New York Times reported that in one study of 143 individuals who received ceramic hips between 2003 and 2005, 10 of the hips developed squeaking. a. Calculate a lower confidence bound at the 95% confidence level for the true proportion of such hips that develop squeaking. b. Interpret the 95% confidence level used in (a). 23. The Pew Forum on Religion and Public Life reported on Dec. 9, 2009, that in a survey of 2003 American adults, 25% said they believed in astrology. a. Calculate and interpret a confidence interval at the 99% confidence level for the proportion of all adult Americans who believe in astrology. b. What sample size would be required for the width of a 99% CI to be at most .05 irrespective of the value of p̂? 24. A sample of 56 research cotton samples resulted in a sample average percentage elongation of 8.17 and a sample standard deviation of 1.42 (“An Apparent Relation Between the Spiral Angle f, the Percent Elongation E1, and the Dimensions of the Cotton Fiber,” Textile Research J., 1978: 407–410). Calculate a 95% large-sample CI for the true average percentage elongation m. What Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 285 7.3 Intervals Based on a Normal Population Distribution assumptions are you making about the distribution of percentage elongation? 25. A state legislator wishes to survey residents of her district to see what proportion of the electorate is aware of her position on using state funds to pay for abortions. a. What sample size is necessary if the 95% CI for p is to have a width of at most .10 irrespective of p? b. If the legislator has strong reason to believe that at least 2/3 of the electorate know of her position, how large a sample size would you recommend? 26. The superintendent of a large school district, having once had a course in probability and statistics, believes that the number of teachers absent on any given day has a Poisson distribution with parameter m. Use the accompanying data on absences for 50 days to obtain a large-sample CI for m. [Hint: The mean and variance of a Poisson variable both equal m, so Z5 X2m 1m/n has approximately a standard normal distribution. Now proceed as in the derivation of the interval for p by making a probability statement (with probability 1 2 a) and solving the resulting inequalities for m — see the argument just after (7.10).] Number of absences 0 1 2 3 4 5 6 7 8 9 10 Frequency 1 4 8 10 8 7 5 3 2 1 1 27. Reconsider the CI (7.10) for p, and focus on a confidence level of 95%. Show that the confidence limits agree quite well with those of the traditional interval (7.11) once two successes and two failures have been appended to the sample [i.e., (7.11) based on x 1 2 S’s in n 1 4 trials]. [Hint: 1.96 < 2. Note: Agresti and Coull showed that this adjustment of the traditional interval also has an actual confidence level close to the nominal level.] 7.3 Intervals Based on a Normal Population Distribution The CI for m presented in Section 7.2 is valid provided that n is large. The resulting interval can be used whatever the nature of the population distribution. The CLT cannot be invoked, however, when n is small. In this case, one way to proceed is to make a specific assumption about the form of the population distribution and then derive a CI tailored to that assumption. For example, we could develop a CI for m when the population is described by a gamma distribution, another interval for the case of a Weibull distribution, and so on. Statisticians have indeed carried out this program for a number of different distributional families. Because the normal distribution is more frequently appropriate as a population model than is any other type of distribution, we will focus here on a CI for this situation. ASSUMPTION The population of interest is normal, so that X1, c, Xn constitutes a random sample from a normal distribution with both m and s unknown. The key result underlying the interval in Section 7.2 was that for large n, the rv Z 5 (X 2 m)/(S/ 1n) has approximately a standard normal distribution. When n is small, S is no longer likely to be close to s, so the variability in the distribution of Z arises from randomness in both the numerator and the denominator. This implies that the probability distribution of (X 2 m)/(S/ 1n) will be more spread out than the standard normal distribution. The result on which inferences are based introduces a new family of probability distributions called t distributions. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 286 CHAPTER 7 Statistical Intervals Based on a Single Sample THEOREM When X is the mean of a random sample of size n from a normal distribution with mean m, the rv X2m S/ 1n T5 (7.13) has a probability distribution called a t distribution with n 2 1 degrees of freedom (df). Properties of t Distributions Before applying this theorem, a discussion of properties of t distributions is in order. Although the variable of interest is still (X 2 m)/(S/ 1n), we now denote it by T to emphasize that it does not have a standard normal distribution when n is small. Recall that a normal distribution is governed by two parameters; each different choice of m in combination with s gives a particular normal distribution. Any particular t distribution results from specifying the value of a single parameter, called the number of degrees of freedom, abbreviated df. We’ll denote this parameter by the Greek letter n. Possible values of n are the positive integers 1, 2, 3, c. So there is a t distribution with 1 df, another with 2 df, yet another with 3 df, and so on. For any fixed value of n, the density function that specifies the associated t curve is even more complicated than the normal density function. Fortunately, we need concern ourselves only with several of the more important features of these curves. Properties of t Distributions Let tn denote the t distribution with n df. 1. 2. 3. 4. Each tn curve is bell-shaped and centered at 0. Each tn curve is more spread out than the standard normal (z) curve. As n increases, the spread of the corresponding tn curve decreases. As n S ` , the sequence of tn curves approaches the standard normal curve (so the z curve is often called the t curve with df 5 ` ). Figure 7.7 illustrates several of these properties for selected values of n. z curve t25 curve t5 curve 0 Figure 7.7 tn and z curves Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 7.3 Intervals Based on a Normal Population Distribution 287 The number of df for T in (7.13) is n 2 1 because, although S is based on the n deviations X1 2 X, c, Xn 2 X, (Xi 2 X) 5 0 implies that only n 2 1 of these are “freely determined.” The number of df for a t variable is the number of freely determined deviations on which the estimated standard deviation in the denominator of T is based. The use of t distribution in making inferences requires notation for capturing t-curve tail areas analogous to za for the z curve. You might think that ta would do the trick. However, the desired value depends not only on the tail area captured but also on df. NOTATION Let ta,n 5 the number on the measurement axis for which the area under the t curve with n df to the right of ta,n is a; ta,n is called a t critical value. For example, t.05,6 is the t critical value that captures an upper-tail area of .05 under the t curve with 6 df. The general notation is illustrated in Figure 7.8. Because t curves are symmetric about zero, 2ta,n captures lower-tail area a. Appendix Table A.5 gives ta,n for selected values of a and n. This table also appears inside the back cover. The columns of the table correspond to different values of a. To obtain t.05,15, go to the a 5 .05 column, look down to the n 5 15 row, and read t.05,15 5 1.753. Similarly, t.05,22 5 1.717 (.05 column, n 5 22 row), and t.01,22 5 2.508. t curve Shaded area 0 t , Figure 7.8 Illustration of a t critical value The values of ta,n exhibit regular behavior as we move across a row or down a column. For fixed n, ta,n increases as a decreases, since we must move farther to the right of zero to capture area a in the tail. For fixed a, as n is increased (i.e., as we look down any particular column of the t table) the value of ta,n decreases. This is because a larger value of n implies a t distribution with smaller spread, so it is not necessary to go so far from zero to capture tail area a. Furthermore, ta,n decreases more slowly as n increases. Consequently, the table values are shown in increments of 2 between 30 df and 40 df and then jump to n 5 50, 60, 120, and finally `. Because t` is the standard normal curve, the familiar za values appear in the last row of the table. The rule of thumb suggested earlier for use of the large-sample CI (if n . 40) comes from the approximate equality of the standard normal and t distributions for n $ 40. The One-Sample t Confidence Interval The standardized variable T has a t distribution with n 2 1 df, and the area under the corresponding t density curve between 2ta/2,n21 and ta/2,n21 is 1 2 a (area a/2 lies in each tail), so P(2ta/ 2, n21 , T , ta/ 2, n21) 5 1 2 a (7.14) Expression (7.14) differs from expressions in previous sections in that T and ta/2,n21 are used in place of Z and za/2, but it can be manipulated in the same manner to obtain a confidence interval for m. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 288 CHAPTER 7 Statistical Intervals Based on a Single Sample PROPOSITION Let x and s be the sample mean and sample standard deviation computed from the results of a random sample from a normal population with mean m. Then a 100(1 2 a)% confidence interval for M is ax 2 ta/2,n21 # s s , x 1 ta/2,n21 # b 1n 1n (7.15) or, more compactly, x 6 ta/2,n21 # s/ 1n. An upper confidence bound for M is x 1 ta,n21 # s 1n and replacing 1 by 2 in this latter expression gives a lower confidence bound for M, both with confidence level 100(1 2 a)%. Example 7.11 Even as traditional markets for sweetgum lumber have declined, large section solid timbers traditionally used for construction bridges and mats have become increasingly scarce. The article “Development of Novel Industrial Laminated Planks from Sweetgum Lumber” (J. of Bridge Engr., 2008: 64–66) described the manufacturing and testing of composite beams designed to add value to low-grade sweetgum lumber. Here is data on the modulus of rupture (psi; the article contained summary data expressed in MPa): 6807.99 6981.46 6906.04 7295.54 7422.69 7637.06 7569.75 6617.17 6702.76 7886.87 6663.28 7437.88 6984.12 7440.17 6316.67 6165.03 6872.39 7093.71 8053.26 7713.65 6991.41 7663.18 7659.50 8284.75 7503.33 6992.23 6032.28 7378.61 7347.95 7674.99 Figure 7.9 shows a normal probability plot from the R software. The straightness of the pattern in the plot provides strong support for assuming that the population distribution of MOR is at least approximately normal. Normal Probability of MOR Sample Quantiles 8000 7500 7000 6500 6000 –2 Figure 7.9 –1 0 1 Theoretical Quantiles 2 A normal probability plot of the modulus of rupture data Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 7.3 Intervals Based on a Normal Population Distribution 289 The sample mean and sample standard deviation are 7203.191 and 543.5400, respectively (for anyone bent on doing hand calculation, the computational burden is eased a bit by subtracting 6000 from each x value to obtain yi 5 xi 2 6000; then g yi 5 36,095.72 and gy2i 5 51,997,668.77, from which y 5 1203.191 and sy 5 sx as given). Let’s now calculate a confidence interval for true average MOR using a confidence level of 95%. The CI is based on n 2 1 5 29 degrees of freedom, so the necessary t critical value is t.025,29 5 2.045. The interval estimate is now x 6 t.025,29 # s 543.5400 5 7203.191 6 (2.045) # 1n 130 5 7203.191 6 202.938 5 (7000.253, 7406.129) We estimate that 7000.253 , m , 7406.129 with 95% confidence. If we use the same formula on sample after sample, in the long run 95% of the calculated intervals will contain m. Since the value of m is not available, we don’t know whether the calculated interval is one of the “good” 95% or the “bad” 5%. Even with the moderately large sample size, our interval is rather wide. This is a consequence of the substantial amount of sample variability in MOR values. A lower 95% confidence bound would result from retaining only the lower confidence limit (the one with 2) and replacing 2.045 with t.05,29 5 1.699. ■ Unfortunately, it is not easy to select n to control the width of the t interval. This is because the width involves the unknown (before the data is collected) s and because n enters not only through 1/ 1n but also through ta/2, n21. As a result, an appropriate n can be obtained only by trial and error. In Chapter 15, we will discuss a small-sample CI for m that is valid provided only that the population distribution is symmetric, a weaker assumption than normality. However, when the population distribution is normal, the t interval tends to be shorter than would be any other interval with the same confidence level. A Prediction Interval for a Single Future Value In many applications, the objective is to predict a single value of a variable to be observed at some future time, rather than to estimate the mean value of that variable. Example 7.12 Consider the following sample of fat content (in percentage) of n 5 10 randomly selected hot dogs (“Sensory and Mechanical Assessment of the Quality of Frankfurters,” J. of Texture Studies, 1990: 395–409): 25.2 21.3 22.8 17.0 29.8 21.0 25.5 16.0 20.9 19.5 Assuming that these were selected from a normal population distribution, a 95% CI for (interval estimate of) the population mean fat content is x 6 t.025,9 # s 5 21.90 6 2.262 1n 5 (18.94, 24.86) # 4.134 5 21.90 6 2.96 110 Suppose, however, you are going to eat a single hot dog of this type and want a prediction for the resulting fat content. A point prediction, analogous to a point estimate, is just x 5 21.90. This prediction unfortunately gives no information about reliability or precision. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 290 CHAPTER 7 Statistical Intervals Based on a Single Sample The general setup is as follows: We have available a random sample X1, X2, c, Xn from a normal population distribution, and wish to predict the value of Xn11, a single future observation (e.g., the lifetime of a single lightbulb to be purchased or the fuel efficiency of a single vehicle to be rented). A point predictor is X, and the resulting prediction error is X 2 Xn11. The expected value of the prediction error is E(X 2 Xn11) 5 E(X) 2 E(Xn11) 5 m 2 m 5 0 Since Xn11 is independent of X1, c, Xn, it is independent of X, so the variance of the prediction error is V(X 2 Xn11) 5 V(X) 1 V(Xn11) 5 s2 1 1 s2 5 s2 a1 1 b n n The prediction error is a linear combination of independent, normally distributed rv’s, so itself is normally distributed. Thus (X 2 Xn11) 2 0 X 2 Xn11 5 1 1 s2 a1 1 b s2 a1 1 b É n n É Z5 has a standard normal distribution. It can be shown that replacing s by the sample standard deviation S (of X1, c, Xn) results in T5 X 2 Xn11 1 11 É n | t distribution with n 2 1 df S Manipulating this T variable as T 5 (X 2 m)/(S/2n) was manipulated in the development of a CI gives the following result. PROPOSITION A prediction interval (PI) for a single observation to be selected from a normal population distribution is x# 6 ta/2,n21 # s B 11 1 n (7.16) The prediction level is 100(1 2 a)%. A lower prediction bound results from replacing ta/2 by ta and discarding the 1 part of (7.16); a similar modification gives an upper prediction bound. The interpretation of a 95% prediction level is similar to that of a 95% confidence level; if the interval (7.16) is calculated for sample after sample, in the long run 95% of these intervals will include the corresponding future values of X. Example 7.13 (Example 7.12 continued) With n 5 10, x 5 21.90, s 5 4.134, and t.025,9 5 2.262, a 95% PI for the fat content of a single hot dog is 21.90 6 (2.262)(4.134) É 11 1 5 21.90 6 9.81 10 5 (12.09, 31.71) This interval is quite wide, indicating substantial uncertainty about fat content. Notice that the width of the PI is more than three times that of the CI. ■ Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 7.3 Intervals Based on a Normal Population Distribution 291 The error of prediction is X 2 Xn11, a difference between two random variables, whereas the estimation error is X 2 m, the difference between a random variable and a fixed (but unknown) value. The PI is wider than the CI because there is more variability in the prediction error (due to Xn11) than in the estimation error. In fact, as n gets arbitrarily large, the CI shrinks to the single value m, and the PI approaches m 6 za/2 # s. There is uncertainty about a single X value even when there is no need to estimate. Tolerance Intervals Consider a population of automobiles of a certain type, and suppose that under specified conditions, fuel efficiency (mpg) has a normal distribution with m 5 30 and s 5 2. Then since the interval from 21.645 to 1.645 captures 90% of the area under the z curve, 90% of all these automobiles will have fuel efficiency values between m 2 1.645s 5 26.71 and m 1 1.645s 5 33.29. But what if the values of m and s are not known? We can take a sample of size n, determine the fuel efficiencies, x and s, and form the interval whose lower limit is x 2 1.645s and whose upper limit is x 1 1.645s. However, because of sampling variability in the estimates of m and s, there is a good chance that the resulting interval will include less than 90% of the population values. Intuitively, to have an a priori 95% chance of the resulting interval including at least 90% of the population values, when x and s are used in place of m and s we should also replace 1.645 by some larger number. For example, when n 5 20, the value 2.310 is such that we can be 95% confident that the interval x 6 2.310s will include at least 90% of the fuel efficiency values in the population. Let k be a number between 0 and 100. A tolerance interval for capturing at least k% of the values in a normal population distribution with a confidence level 95% has the form x 6 (tolerance critical value) # s Tolerance critical values for k 5 90, 95, and 99 in combination with various sample sizes are given in Appendix Table A.6. This table also includes critical values for a confidence level of 99% (these values are larger than the corresponding 95% values). Replacing 6 by 1 gives an upper tolerance bound, and using 2 in place of 6 results in a lower tolerance bound. Critical values for obtaining these one-sided bounds also appear in Appendix Table A.6. Example 7.14 As part of a larger project to study the behavior of stressed-skin panels, a structural component being used extensively in North America, the article “Time-Dependent Bending Properties of Lumber” (J. of Testing and Eval., 1996: 187–193) reported on various mechanical properties of Scotch pine lumber specimens. Consider the following observations on modulus of elasticity (MPa) obtained 1 minute after loading in a certain configuration: 10,490 13,630 16,620 13,260 17,300 14,370 15,480 11,700 12,970 15,470 17,260 17,840 13,400 14,070 13,900 14,760 There is a pronounced linear pattern in a normal probability plot of the data. Relevant summary quantities are n 5 16, x 5 14,532.5, s 5 2055.67. For a confidence level of 95%, a two-sided tolerance interval for capturing at least 95% of the modulus of elasticity values for specimens of lumber in the population sampled uses the tolerance critical value of 2.903. The resulting interval is 14,532.5 6 (2.903)(2055.67) 5 14,532.5 6 5967.6 5 (8,564.9, 20,500.1) Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 292 CHAPTER 7 Statistical Intervals Based on a Single Sample We can be highly confident that at least 95% of all lumber specimens have modulus of elasticity values between 8,564.9 and 20,500.1. The 95% CI for m is (13,437.3, 15,627.7), and the 95% prediction interval for the modulus of elasticity of a single lumber specimen is (10,017.0, 19,048.0). Both the prediction interval and the tolerance interval are substantially wider than the confidence interval. ■ Intervals Based on Nonnormal Population Distributions The one-sample t CI for m is robust to small or even moderate departures from normality unless n is quite small. By this we mean that if a critical value for 95% confidence, for example, is used in calculating the interval, the actual confidence level will be reasonably close to the nominal 95% level. If, however, n is small and the population distribution is highly nonnormal, then the actual confidence level may be considerably different from the one you think you are using when you obtain a particular critical value from the t table. It would certainly be distressing to believe that your confidence level is about 95% when in fact it was really more like 88%! The bootstrap technique, introduced in Section 7.1, has been found to be quite successful at estimating parameters in a wide variety of nonnormal situations. In contrast to the confidence interval, the validity of the prediction and tolerance intervals described in this section is closely tied to the normality assumption. These latter intervals should not be used in the absence of compelling evidence for normality. The excellent reference Statistical Intervals, cited in the bibliography at the end of this chapter, discusses alternative procedures of this sort for various other situations. EXERCISES Section 7.3 (28–41) 28. Determine the values of the following quantities: a. t.1,15 b. t.05,15 c. t.05,25 d. t.05,40 e. t.005,40 29. Determine the t critical value(s) that will capture the desired t-curve area in each of the following cases: a. Central area .95, df 10 b. Central area .95, df 20 c. Central area .99, df 20 d. Central area .99, df 50 e. Upper-tail area .01, df 25 f. Lower-tail area .025, df 5 30. Determine the t critical value for a two-sided confidence interval in each of the following situations: a. Confidence level 95%, df 10 b. Confidence level 95%, df 15 c. Confidence level 99%, df 15 d. Confidence level 99%, n 5 e. Confidence level 98%, df 24 f. Confidence level 99%, n 38 31. Determine the t critical value for a lower or an upper confidence bound for each of the situations described in Exercise 30. 32. According to the article “Fatigue Testing of Condoms” (Polymer Testing, 2009: 567–571), “tests currently used for condoms are surrogates for the challenges they face in use,” including a test for holes, an inflation test, a package seal test, and tests of dimensions and lubricant quality (all fertile territory for the use of statistical methodology!). The investigators developed a new test that adds cyclic strain to a level well below breakage and determines the number of cycles to break. A sample of 20 condoms of one particular type resulted in a sample mean number of 1584 and a sample standard deviation of 607. Calculate and interpret a confidence interval at the 99% confidence level for the true average number of cycles to break. [Note: The article presented the results of hypothesis tests based on the t distribution; the validity of these depends on assuming normal population distributions.] 33. The article “Measuring and Understanding the Aging of Kraft Insulating Paper in Power Transformers” (IEEE Electrical Insul. Mag., 1996: 28–34) contained the following observations on degree of polymerization for paper specimens for which viscosity times concentration fell in a certain middle range: 418 421 421 422 425 427 431 434 437 439 446 447 448 453 454 463 465 Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 293 7.3 Intervals Based on a Normal Population Distribution a. Construct a boxplot of the data and comment on any interesting features. b. Is it plausible that the given sample observations were selected from a normal distribution? c. Calculate a two-sided 95% confidence interval for true average degree of polymerization (as did the authors of the article). Does the interval suggest that 440 is a plausible value for true average degree of polymerization? What about 450? 34. A sample of 14 joint specimens of a particular type gave a sample mean proportional limit stress of 8.48 MPa and a sample standard deviation of .79 MPa (“Characterization of Bearing Strength Factors in Pegged Timber Connections,” J. of Structural Engr., 1997: 326–332). a. Calculate and interpret a 95% lower confidence bound for the true average proportional limit stress of all such joints. What, if any, assumptions did you make about the distribution of proportional limit stress? b. Calculate and interpret a 95% lower prediction bound for the proportional limit stress of a single joint of this type. 35. Silicone implant augmentation rhinoplasty is used to correct congenital nose deformities. The success of the procedure depends on various biomechanical properties of the human nasal periosteum and fascia. The article “Biomechanics in Augmentation Rhinoplasty” (J. of Med. Engr. and Tech., 2005: 14–17) reported that for a sample of 15 (newly deceased) adults, the mean failure strain (%) was 25.0, and the standard deviation was 3.5. a. Assuming a normal distribution for failure strain, estimate true average strain in a way that conveys information about precision and reliability. b. Predict the strain for a single adult in a way that conveys information about precision and reliability. How does the prediction compare to the estimate calculated in part (a)? 36. The n 5 26 observations on escape time given in Exercise 36 of Chapter 1 give a sample mean and sample standard deviation of 370.69 and 24.36, respectively. a. Calculate an upper confidence bound for population mean escape time using a confidence level of 95%. b. Calculate an upper prediction bound for the escape time of a single additional worker using a prediction level of 95%. How does this bound compare with the confidence bound of part (a)? c. Suppose that two additional workers will be chosen to participate in the simulated escape exercise. Denote their escape times by X27 and X28, and let Xnew denote the average of these two values. Modify the formula for a PI for a single x value to obtain a PI for Xnew, and calculate a 95% two-sided interval based on the given escape data. 37. A study of the ability of individuals to walk in a straight line (“Can We Really Walk Straight?” Amer. J. of Physical Anthro., 1992: 19–27) reported the accompanying data on cadence (strides per second) for a sample of n 5 20 randomly selected healthy men. .95 .85 .92 .95 .93 .86 1.00 .92 .85 .81 .78 .93 .93 1.05 .93 1.06 1.06 .96 .81 .96 A normal probability plot gives substantial support to the assumption that the population distribution of cadence is approximately normal. A descriptive summary of the data from Minitab follows: Variable N Mean Median cadence 20 0.9255 0.9300 TrMean 0.9261 StDev 0.0809 Variable cadence Q1 0.8525 Q3 0.9600 Min Max 0.7800 1.0600 SEMean 0.0181 a. Calculate and interpret a 95% confidence interval for population mean cadence. b. Calculate and interpret a 95% prediction interval for the cadence of a single individual randomly selected from this population. c. Calculate an interval that includes at least 99% of the cadences in the population distribution using a confidence level of 95%. 38. A sample of 25 pieces of laminate used in the manufacture of circuit boards was selected, and the amount of warpage (in.) under particular conditions was determined for each piece, resulting in a sample mean warpage of .0635 and a sample standard deviation of .0065. a. Calculate a prediction for the amount of warpage of a single piece of laminate in a way that provides information about precision and reliability. b. Calculate an interval for which you can have a high degree of confidence that at least 95% of all pieces of laminate result in amounts of warpage that are between the two limits of the interval. 39. Exercise 72 of Chapter 1 gave the following observations on a receptor binding measure (adjusted distribution volume) for a sample of 13 healthy individuals: 23, 39, 40, 41, 43, 47, 51, 58, 63, 66, 67, 69, 72. a. Is it plausible that the population distribution from which this sample was selected is normal? b. Calculate an interval for which you can be 95% confident that at least 95% of all healthy individuals in the population have adjusted distribution volumes lying between the limits of the interval. c. Predict the adjusted distribution volume of a single healthy individual by calculating a 95% prediction interval. How does this interval’s width compare to the width of the interval calculated in part (b)? 40. Exercise 13 of Chapter 1 presented a sample of n 5 153 observations on ultimate tensile strength, and Exercise 17 of the previous section gave summary quantities and requested a large-sample confidence interval. Because the sample size is large, no assumptions about the population distribution are required for the validity of the CI. a. Is any assumption about the tensile-strength distribution required prior to calculating a lower prediction bound for Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 294 CHAPTER 7 Statistical Intervals Based on a Single Sample the tensile strength of the next specimen selected using the method described in this section? Explain. b. Use a statistical software package to investigate the plausibility of a normal population distribution. c. Calculate a lower prediction bound with a prediction level of 95% for the ultimate tensile strength of the next specimen selected. 41. A more extensive tabulation of t critical values than what appears in this book shows that for the t distribution with 20 df, the areas to the right of the values .687, .860, and 1.064 are .25, .20, and .15, respectively. What is the confidence level for each of the following three confidence intervals for the mean m of a normal population distribution? Which of the three intervals would you recommend be used, and why? a. (x 2 .687s/ 121, x 1 1.725s/ 121) b. (x 2 .860s/ 121, x 1 1.325s/ 121) c. (x 2 1.064s/ 121, x 1 1.064s/ 121) 7.4 Confidence Intervals for the Variance and Standard Deviation of a Normal Population Although inferences concerning a population variance s2 or standard deviation s are usually of less interest than those about a mean or proportion, there are occasions when such procedures are needed. In the case of a normal population distribution, inferences are based on the following result concerning the sample variance S2. THEOREM Let X1, X2, c, Xn be a random sample from a normal distribution with parameters m and s2. Then the rv (n 2 1)S 2 g(Xi 2 X)2 5 s2 s2 has a chi-squared (x2) probability distribution with n 2 1 df. As discussed in Sections 4.4 and 7.1, the chi-squared distribution is a continuous probability distribution with a single parameter n, called the number of degrees of freedom, with possible values 1, 2, 3, . . . . The graphs of several x2 probability density functions (pdf’s) are illustrated in Figure 7.10. Each pdf f (x; n) is positive only for x . 0, and each has a positive skew (long upper tail), though the distribution moves rightward and becomes more symmetric as n increases. To specify inferential procedures that use the chi-squared distribution, we need notation analogous to that for a t critical value ta,n. f(x; ) 8 12 20 x Figure 7.10 NOTATION Graphs of chi-squared density functions Let x2a,n, called a chi-squared critical value, denote the number on the horizontal axis such that a of the area under the chi-squared curve with n df lies to the right of x2a,n. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 7.4 Confidence Intervals for the Variance and Standard Deviation of a Normal Population 295 Symmetry of t distributions made it necessary to tabulate only upper-tailed t critical values (ta,n for small values of a). The chi-squared distribution is not symmetric, so Appendix Table A.7 contains values of x2a,n both for a near 0 and near 1, as illustrated in Figure 7.11(b). For example, x2.025,14 5 26.119, and x 2.95,20 (the 5th percentile) 5 10.851. Each shaded area .01 2 density curve Shaded area 2, 2 .99, (a) 2 .01, (b) Figure 7.11 x2a,n notation illustrated The rv (n 2 1)S 2/s2 satisfies the two properties on which the general method for obtaining a CI is based: It is a function of the parameter of interest s2, yet its probability distribution (chi-squared) does not depend on this parameter. The area under a chi-squared curve with n df to the right of x 2a/2,n is a/2, as is the area to the left of x212a/2,n. Thus the area captured between these two critical values is 1 2 a. As a consequence of this and the theorem just stated, Pax212a/2,n21 , (n 2 1)S 2 , x2a/2,n21 b 5 1 2 a s2 (7.17) The inequalities in (7.17) are equivalent to (n 2 1)S 2 (n 2 1)S 2 , s2 , 2 2 xa/2,n21 x12a/2,n21 Substituting the computed value s2 into the limits gives a CI for s2, and taking square roots gives an interval for s. A 100(1 2 a)% confidence interval for the variance s2 of a normal population has lower limit (n 2 1)s 2/x2a/2,n21 and upper limit (n 2 1)s 2/x212a/2,n21 A confidence interval for s has lower and upper limits that are the square roots of the corresponding limits in the interval for s2. An upper or a lower confidence bound results from replacing a/2 with a in the corresponding limit of the CI. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. 296 CHAPTER 7 Statistical Intervals Based on a Single Sample Example 7.15 The accompanying data on breakdown voltage of electrically stressed circuits was read from a normal probability plot that appeared in the article “Damage of Flexible Printed Wiring Boards Associated with Lightning-Induced Voltage Surges” (IEEE Transactions on Components, Hybrids, and Manuf. Tech., 1985: 214–220). The straightness of the plot gave strong support to the assumption that breakdown voltage is approximately normally distributed. 1470 1510 1690 1740 1900 2000 2030 2100 2200 2290 2380 2390 2480 2500 2580 2700 2190 Let s2 denote the variance of the breakdown voltage distribution. The computed value of the sample variance is s 2 5 137, 324.3, the point estimate of s2. With df 5 n 2 1 5 16, a 95% CI requires x2.975,16 5 6.908 and x2.025,16 5 28.845. The interval is a 16(137,324.3) 16(137,324.3) , b 5 (76,172.3, 318, 064.4) 28.845 6.908 Taking the square root of each endpoint yields (276.0, 564.0) as the 95% CI for s. These intervals are quite wide, reflecting substantial variability in breakdown voltage in combination with a small sample size. ■ CIs for s2 and s when the population distribution is not normal can be difficult to obtain. For such cases, consult a knowledgeable statistician. EXERCISES Section 7.4 (42–46) 42. Determine the values of the following quantities: a. x2.1,15 b. x2.1,25 2 c. x.01,25 d. x2.005,25 e. x2.99,25 f. x2.995,25 43. Determine the following: a. The 95th percentile of the chi-squared distribution with n 5 10 b. The 5th percentile of the chi-squared distribution with n 5 10 c. P(10.98 # x2 # 36.78), where x2 is a chi-squared rv with n 5 22 d. P(x2 , 14.611 or x2 . 37.652), where x2 is a chisquared rv with n 5 25 44. The amount of lateral expansion (mils) was determined for a sample of n 5 9 pulsed-power gas metal arc welds used in LNG ship containment tanks. The resulting sample standard deviation was s 5 2.81 mils. Assuming normality, derive a 95% CI for s2 and for s. 45. The following observations were made on fracture toughness of a base plate of 18% nickel maraging steel [“Fracture Testing of Weldments,” ASTM Special Publ. No. 381, 1965: 328–356 (in ksi 1in., given in increasing order)]: 69.5 71.9 72.6 73.1 73.3 73.5 75.5 75.7 75.8 76.1 76.2 76.2 77.0 77.9 78.1 79.6 79.7 79.9 80.1 82.2 83.7 93.7 Calculate a 99% CI for the standard deviation of the fracturetoughness distribution. Is this interval valid whatever the nature of the distribution? Explain. 46. The article “Concrete Pressure on Formwork” (Mag. of Concrete Res., 2009: 407–417) gave the following observations on maximum concrete pressure (kN/m2): 33.2 41.8 37.3 40.2 36.7 39.1 36.2 36.0 35.2 36.7 38.9 35.8 35.2 40.1 41.8 a. Is it plausible that this sample was selected from a normal population distribution? b. Calculate an upper confidence bound with confidence level 95% for the population standard deviation of maximum pressure. Copyright 2010 Cengage Learning. All Rights Reserved. May not be copied, scanned, or duplicated, in whole or in part. Due to electronic rights, some third party content may be suppressed from the eBook and/or eChapter(s). Editorial review has deemed that any suppressed content does not materially affect the overall learning experience. Cengage Learning reserves the right to remove additional content at any time if subsequent rights restrictions require it. Supplementary Exercises SUPPLEMENTARY EXERCISES (47–62) 47. Example 1.11 introduced the accompanying observations on bond strength. 11.5 13.4 4.9 3.6 8.2 5.2 12.1 17.1 10.7 3.4 10.7 4.8 9.9 9.3 15.2 20.6 14.2 4.1 9.3 5.6 8.5 25.5 7.6 3.8 7.8 5.7 4.2 13.8 5.2 3.7 6.2 5.4 4.0 12.6 5.5 3.6 6.6 5.2 3.9 13.1 5.1 3.6 7.0 5.1 3.8 8.9 5.0 3.6 a. Estimate true average bond strength in a way that conveys information about pre

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